Synthetic Routes to Approved Drugs Containing a Spirocycle

The use of spirocycles in drug discovery and medicinal chemistry has been booming in the last two decades. This has clearly translated into the landscape of approved drugs. Among two dozen clinically used medicines containing a spirocycle, 50% have been approved in the 21st century. The present review focuses on the notable synthetic routes to such drugs invented in industry and academia, and is intended to serve as a useful reference source of synthetic as well as general drug information for researchers engaging in the design of new spirocyclic scaffolds for medicinal use or embarking upon analog syntheses inspired by the existing approved drugs.


Introduction
Spirocycles are becoming increasingly popular in drug discovery. Inherently threedimensional, these high-F sp3 (F sp3 = number of sp 3 hybridized carbons/total carbon count) motifs are expected to rid drug candidate molecules of many liabilities which would be inevitably encountered with the formerly typical scaffolds built on flat aromatic carboand heterocycles. Hence it is perhaps unsurprising that the trend (articulated for the first time in the Escape from the Flatland publication by Lovering and colleagues [1]) has now translated itself in an increasing number of approved drugs containing spirocyclic motifs. We and these colleagues recently published a review article on the use of spirocycles in drug discovery [2]. In this review, we partly touched upon the syntheses of approved spirocyclic drugs. However, that overview was far from exhaustive. Moreover, it only episodically touched upon approved spirocyclic drugs, also focusing on advanced, though not approved, drug candidates. Considering the apparent interest in the subject from the research community (at the time of writing this review, publication [2] was cited over 100 times in the 1.5 years since its appearance in the literature), we thought it prudent to compile a more comprehensive compendium of synthetic routes to approved drugs containing a spirocyclic motif, with a particular emphasis on alternative synthetic approaches to the same drug molecule, if such exist. The present review is the result of realizing that intent. The review covers 23 drug molecules approved for medical use over the period of 1959 to 2021.

Griseofulvin
Griseofulvin ( Figure 1) is an antifungal agent used to treat fungal infections of the fingernails and toes. It is one of the earliest spirocyclic drugs, and was approved in 1959. The exact mechanism of its action remains unclear, with putative targets including tubulin

Griseofulvin
Griseofulvin (Figure 1) is an antifungal agent used to treat fungal infections of the fingernails and toes. It is one of the earliest spirocyclic drugs, and was approved in 1959. The exact mechanism of its action remains unclear, with putative targets including tubulin beta chain and keratin, type I cytoskeletal 12 through which griseofulvin interferes with fungal mitosis. Two total syntheses of griseofulvin were accomplished in the 1990s. Yamoto and coworkers reported the synthesis of racemic griseofulfin in 1990 [3]. The synthesis commenced with 7-chloro-4,6-dimethoxy-3(2H)-benzofuranone (1) which was condensed with acetaldehyde diethyl acetal in the presence of Ti(IV) chloride to give (Z)-configured ethylidene derivative 2. In order to bring the olefin configuration to the desired (E), compound 2 was subjected to somewhat low-yielding photochemical isomerization. The (E)-configured olefin 3 was now set for a Diels-Alder reaction with diene 4 (10 equiv.), which was accomplished in refluxing toluene to furnish racemic griseofulvin in 46% yield (Scheme 1). Scheme 1. Synthesis of dl-griseofulvin by Yamoto and co-workers [3].
Pirrung and co-workers reported the first asymmetric synthesis of natural enantiomer (+)-griseofulvin in 1991 [4]. Commercially available phenol 5 was regiospecifically chlorinated to provide intermediate 6. The la er underwent a Fries rearrangement in the presence of aluminum chloride and the liberated phenol was involved in the Mitsunobu coupling with non-racemic allylic alcohol 7 to give rise to pentasubstituted benzene building block 8. The acetyl group in the la er was deprotonated and methoxycarbonylated by treatment with Mander's reagent (9) and the resulting β-keto ester was subjected to Regi diazo transfer to provide the diazo compound 10. Decomposition of the la er was accomplished with the use of rhodium pivalate catalyst and the resulting rhodium carbene underwent intramolecular trapping with the nearby oxygen atom, followed by sigmatropic rearrangement to give benzofuranone 11. Conversion of the la er to non-racemic methyl ketone 14 was accomplished via ozonolysis, the Wi ig reaction with phosphonium ylide 12, tert-butyl ester cleavage with TFA and decarboxylation on treatment with diphenylphosphoryl Two total syntheses of griseofulvin were accomplished in the 1990s. Yamoto and co-workers reported the synthesis of racemic griseofulfin in 1990 [3]. The synthesis commenced with 7-chloro-4,6-dimethoxy-3(2H)-benzofuranone (1) which was condensed with acetaldehyde diethyl acetal in the presence of Ti(IV) chloride to give (Z)-configured ethylidene derivative 2. In order to bring the olefin configuration to the desired (E), compound 2 was subjected to somewhat low-yielding photochemical isomerization. The (E)-configured olefin 3 was now set for a Diels-Alder reaction with diene 4 (10 equiv.), which was accomplished in refluxing toluene to furnish racemic griseofulvin in 46% yield (Scheme 1).

Griseofulvin
Griseofulvin (Figure 1) is an antifungal agent used to treat fungal infections of the fingernails and toes. It is one of the earliest spirocyclic drugs, and was approved in 1959. The exact mechanism of its action remains unclear, with putative targets including tubulin beta chain and keratin, type I cytoskeletal 12 through which griseofulvin interferes with fungal mitosis. Two total syntheses of griseofulvin were accomplished in the 1990s. Yamoto and coworkers reported the synthesis of racemic griseofulfin in 1990 [3]. The synthesis commenced with 7-chloro-4,6-dimethoxy-3(2H)-benzofuranone (1) which was condensed with acetaldehyde diethyl acetal in the presence of Ti(IV) chloride to give (Z)-configured ethylidene derivative 2. In order to bring the olefin configuration to the desired (E), compound 2 was subjected to somewhat low-yielding photochemical isomerization. The (E)-configured olefin 3 was now set for a Diels-Alder reaction with diene 4 (10 equiv.), which was accomplished in refluxing toluene to furnish racemic griseofulvin in 46% yield (Scheme 1). Scheme 1. Synthesis of dl-griseofulvin by Yamoto and co-workers [3].
Pirrung and co-workers reported the first asymmetric synthesis of natural enantiomer (+)-griseofulvin in 1991 [4]. Commercially available phenol 5 was regiospecifically chlorinated to provide intermediate 6. The la er underwent a Fries rearrangement in the presence of aluminum chloride and the liberated phenol was involved in the Mitsunobu coupling with non-racemic allylic alcohol 7 to give rise to pentasubstituted benzene building block 8. The acetyl group in the la er was deprotonated and methoxycarbonylated by treatment with Mander's reagent (9) and the resulting β-keto ester was subjected to Regi diazo transfer to provide the diazo compound 10. Decomposition of the la er was accomplished with the use of rhodium pivalate catalyst and the resulting rhodium carbene underwent intramolecular trapping with the nearby oxygen atom, followed by sigmatropic rearrangement to give benzofuranone 11. Conversion of the la er to non-racemic methyl ketone 14 was accomplished via ozonolysis, the Wi ig reaction with phosphonium ylide 12, tert-butyl ester cleavage with TFA and decarboxylation on treatment with diphenylphosphoryl Scheme 1. Synthesis of dl-griseofulvin by Yamoto and co-workers [3].
Pirrung and co-workers reported the first asymmetric synthesis of natural enantiomer (+)-griseofulvin in 1991 [4]. Commercially available phenol 5 was regiospecifically chlorinated to provide intermediate 6. The latter underwent a Fries rearrangement in the presence of aluminum chloride and the liberated phenol was involved in the Mitsunobu coupling with non-racemic allylic alcohol 7 to give rise to pentasubstituted benzene building block 8. The acetyl group in the latter was deprotonated and methoxycarbonylated by treatment with Mander's reagent (9) and the resulting β-keto ester was subjected to Regitz diazo transfer to provide the diazo compound 10. Decomposition of the latter was accomplished with the use of rhodium pivalate catalyst and the resulting rhodium carbene underwent intramolecular trapping with the nearby oxygen atom, followed by sigmatropic rearrangement to give benzofuranone 11. Conversion of the latter to non-racemic methyl ketone 14 was accomplished via ozonolysis, the Wittig reaction with phosphonium ylide 12, tert-butyl ester cleavage with TFA and decarboxylation on treatment with diphenylphosphoryl azide (13), followed by exposure to refluxing aqueous hydrochloric acid. Finally, methyl ketone 14 was subjected to treatment with sodium methoxide on which it underwent the Dieckmann cyclization. The resulting cyclohexane-1,3-dione (griseofulvinic acid) was O-methylated with diazomethane to furnish (+)-griseofulvin (Scheme 2). azide (13), followed by exposure to refluxing aqueous hydrochloric acid. Finally, methyl ketone 14 was subjected to treatment with sodium methoxide on which it underwent the Dieckmann cyclization. The resulting cyclohexane-1,3-dione (griseofulvinic acid) was Omethylated with diazomethane to furnish (+)-griseofulvin (Scheme 2). Scheme 2. Synthesis of (+)-griseofulvin by Pirrung and co-workers [4].

Spironolactone
Spironolactone ( Figure 2) is a relatively old multi-target drug that is primarily used to treat high blood pressure and heart failure. Additional therapeutic applications of this drug include edema, cirrhosis of the liver and primary aldosteronism. The mechanism of action of spironolactone includes binding to intracellular mineralocorticoid receptors (MRs) in kidney epithelial cells, which leads to the inhibition of aldosterone binding [5].

Spironolactone
Spironolactone ( Figure 2) is a relatively old multi-target drug that is primarily used to treat high blood pressure and heart failure. Additional therapeutic applications of this drug include edema, cirrhosis of the liver and primary aldosteronism. The mechanism of action of spironolactone includes binding to intracellular mineralocorticoid receptors (MRs) in kidney epithelial cells, which leads to the inhibition of aldosterone binding [5].

Spironolactone
Spironolactone ( Figure 2) is a relatively old multi-target drug that is primarily used to treat high blood pressure and heart failure. Additional therapeutic applications of this drug include edema, cirrhosis of the liver and primary aldosteronism. The mechanism of action of spironolactone includes binding to intracellular mineralocorticoid receptors (MRs) in kidney epithelial cells, which leads to the inhibition of aldosterone binding [5].  The first industrial synthesis of spironolactone was reported in 1957-1959 by Cella and co-workers of G. D. Searle and Co. [6][7][8]. The synthesis commenced with previously reported ethynyl steroid building block 15. It was carbonylated at the alkyne terminus by treatment with methyl magnesium bromide, followed by quenching with carbon dioxide. Hydrogenation of alkyne 16 over the Lindlar catalyst elaborated the propionic acid side chain in 17 required for the formation of the spirocyclic lactone at the next step. Cyclization on treatment with p-toluenesulfonic acid yielded unsaturated lactone which was hydrogenated over palladium on carbon to yield spirocyclic lactone 18.
Oppenauer oxidation of the alcohol functionality in 18 was accompanied by the migration of the double bond to give α,β-unsaturated ketone 19. The conjugated system in 19 was extended by γ,δ-oxidation with chloranil to give compound 20, and set the scene for the conjugate addition of thioacetic acid at the d-position, which proceeded with high diastereoselectivity and furnished spironolactone in 86% yield (Scheme 3).
The first industrial synthesis of spironolactone was reported in 1957-1959 by Cella and co-workers of G. D. Searle and Co. [6][7][8]. The synthesis commenced with previously reported ethynyl steroid building block 15. It was carbonylated at the alkyne terminus by treatment with methyl magnesium bromide, followed by quenching with carbon dioxide. Hydrogenation of alkyne 16 over the Lindlar catalyst elaborated the propionic acid side chain in 17 required for the formation of the spirocyclic lactone at the next step. Cyclization on treatment with p-toluenesulfonic acid yielded unsaturated lactone which was hydrogenated over palladium on carbon to yield spirocyclic lactone 18.
Oppenauer oxidation of the alcohol functionality in 18 was accompanied by the migration of the double bond to give α,β-unsaturated ketone 19. The conjugated system in 19 was extended by γ,δ-oxidation with chloranil to give compound 20, and set the scene for the conjugate addition of thioacetic acid at the d-position, which proceeded with high diastereoselectivity and furnished spironolactone in 86% yield (Scheme 3). Scheme 3. Spironolactone synthesis by G. D. Searle and Co [6][7][8].
Another synthetic approach of spironolactone was patented in 1980 by Ciba Geigy scientists [9]. The synthesis stems from dehydroepiandrosterone (21), which was treated with 3-chloropropionaldehyde ethylene acetal and lithium to furnish tertiary alcohol 22 in diastereoselective fashion. The following sequence of steps (which proceeded in 75% overall yield) included bromination of the double bond, oxidation of the secondary alcohol to ketone and, finally, base-promoted double dehydrobromination, which led to α,β,γ,δ-unsaturated ketone (androstadienone) 23. Interestingly, the conjugate addition of thioacetic acid was in this case performed prior to the elaboration of the spirocyclic lactone in the last step. Thioacetic acid also caused the deprotection of the aldehyde to furnish 24. Oxidation of the aldehyde to the carboxylic acid in the presence of sulfuric acid brought about the closure of the lactone ring and led to the formation of spironolactone in 51% yield from 23 (Scheme 4). Scheme 3. Spironolactone synthesis by G. D. Searle and Co [6][7][8].
Another synthetic approach of spironolactone was patented in 1980 by Ciba Geigy scientists [9]. The synthesis stems from dehydroepiandrosterone (21), which was treated with 3-chloropropionaldehyde ethylene acetal and lithium to furnish tertiary alcohol 22 in diastereoselective fashion. The following sequence of steps (which proceeded in 75% overall yield) included bromination of the double bond, oxidation of the secondary alcohol to ketone and, finally, base-promoted double dehydrobromination, which led to α,β,γ,δunsaturated ketone (androstadienone) 23. Interestingly, the conjugate addition of thioacetic acid was in this case performed prior to the elaboration of the spirocyclic lactone in the last step. Thioacetic acid also caused the deprotection of the aldehyde to furnish 24. Oxidation of the aldehyde to the carboxylic acid in the presence of sulfuric acid brought about the closure of the lactone ring and led to the formation of spironolactone in 51% yield from 23 (Scheme 4).
A fundamentally different route to spironolactone performed in multigram scale was developed by the Chemical Process Research and Development scientists at The Upjohn Co. in the late 1980s [10]. The synthesis relied on the readily available ethynyl steroid building block 25, the ketone group of which was protected as ethylene glycol ketal in the first step.
The key transformation which led to the formation of spirocyclic lactol intermediate 27 was rhodium-catalyzed hydroformylation at elevated temperature and pressure. Oxidation of 27 to lactone was achieved with PDC and the ketal protecting group was removed to afford 28. The formation of α,β,γ,δ-unsaturated ketone 20 was achieved with chloranil (vide supra). and conjugate addition of thioacetic acid (catalyzed by TMSOTf) at the δ-position furnished spironolactone (Scheme 5). Scheme 4. Ciba Geigy industrial synthesis of spironolactone [9].
A fundamentally different route to spironolactone performed in multigram scale was developed by the Chemical Process Research and Development scientists at The Upjohn Co. in the late 1980s [10]. The synthesis relied on the readily available ethynyl steroid building block 25, the ketone group of which was protected as ethylene glycol ketal in the first step. The key transformation which led to the formation of spirocyclic lactol intermediate 27 was rhodium-catalyzed hydroformylation at elevated temperature and pressure. Oxidation of 27 to lactone was achieved with PDC and the ketal protecting group was removed to afford 28. The formation of α,β,γ,δ-unsaturated ketone 20 was achieved with chloranil (vide supra). and conjugate addition of thioacetic acid (catalyzed by TMSOTf) at the δ-position furnished spironolactone (Scheme 5). Scheme 4. Ciba Geigy industrial synthesis of spironolactone [9].
Among many non-industrial syntheses of spironolactone described in the literature [5], the most recent one reported by Nagamitsu, Ohtawa and co-workers is quite notable [11]. The synthesis commences with dehydroepiandrosterone (21) and is reliant on the innovative approach to γ-lactonization of homopropargyl alcohols, which involves terminal borylation of a homopropargyl moiety followed by m-CPBA oxidation. The la er sequence leads to the transformation of the alkyne moiety into a ketene intermediate which is trapped intramolecularly to give a γ-lactone. Hence, the starting material 21 was treated with propargyl magnesium bromide (under Hg(II) catalysis) to give homopropargyl alcohol 29 in nearly quantitative yield. Application of the γ-lactonization protocol described above led to the formation of spirocyclic lactone 18. Oxidation of the secondary alcohol moiety in the la er with Dess-Martin periodinane (DMP) gave γ,δunsaturated ketone 28. Transformation of the la er into spironolactone was analogous to Scheme 5. The Upjohn Co. synthesis of spironolactone [10]. Among many non-industrial syntheses of spironolactone described in the literature [5], the most recent one reported by Nagamitsu, Ohtawa and co-workers is quite notable [11]. The synthesis commences with dehydroepiandrosterone (21) and is reliant on the innovative approach to γ-lactonization of homopropargyl alcohols, which involves terminal borylation of a homopropargyl moiety followed by m-CPBA oxidation. The latter sequence leads to the transformation of the alkyne moiety into a ketene intermediate which is trapped intramolecularly to give a γ-lactone. Hence, the starting material 21 was treated with propargyl magnesium bromide (under Hg(II) catalysis) to give homopropargyl alco-Molecules 2023, 28, 4209 6 of 47 hol 29 in nearly quantitative yield. Application of the γ-lactonization protocol described above led to the formation of spirocyclic lactone 18. Oxidation of the secondary alcohol moiety in the latter with Dess-Martin periodinane (DMP) gave γ,δ-unsaturated ketone 28. Transformation of the latter into spironolactone was analogous to the Upjohn Co. synthesis described above. Oxidation with chloranil installed the polyunsaturated ketone system (20) which is suitable for the conjugate addition of thioacetic acid (also TMSOTf-catalyzed in this case), resulting in the formation of spironolactone (Scheme 6).
[5], the most recent one reported by Nagamitsu, Ohtawa and co-workers is quite notable [11]. The synthesis commences with dehydroepiandrosterone (21) and is reliant on the innovative approach to γ-lactonization of homopropargyl alcohols, which involves terminal borylation of a homopropargyl moiety followed by m-CPBA oxidation. The la er sequence leads to the transformation of the alkyne moiety into a ketene intermediate which is trapped intramolecularly to give a γ-lactone. Hence, the starting material 21 was treated with propargyl magnesium bromide (under Hg(II) catalysis) to give homopropargyl alcohol 29 in nearly quantitative yield. Application of the γ-lactonization protocol described above led to the formation of spirocyclic lactone 18. Oxidation of the secondary alcohol moiety in the la er with Dess-Martin periodinane (DMP) gave γ,δunsaturated ketone 28. Transformation of the la er into spironolactone was analogous to the Upjohn Co. synthesis described above. Oxidation with chloranil installed the polyunsaturated ketone system (20) which is suitable for the conjugate addition of thioacetic acid (also TMSOTf-catalyzed in this case), resulting in the formation of spironolactone (Scheme 6). Scheme 6. Synthesis of spironolactone via γ-lactonization of homopropargyl alcohol.

Fluspirilene
Fluspirilene (Figure 3), a spirocyclic antipsychotic drug was discovered at Janssen Pharmaceutica in 1963, and by 1970 it had been approved for the treatment of schizophrenia [12]. The primary molecular targets of fluspirilene in the central nervous system are dopamine D 2 and serotonin 5HT 2A receptors, as well as α1 subunit of voltage-dependent calcium channel [13].

Fluspirilene
Fluspirilene (Figure 3), a spirocyclic antipsychotic drug was discovered at Janssen Pharmaceutica in 1963, and by 1970 it had been approved for the treatment of schizophrenia [12]. The primary molecular targets of fluspirilene in the central nervous system are dopamine D2 and serotonin 5HT2A receptors, as well as α1 subunit of voltagedependent calcium channel [13]. Fluspirilene is an old drug, and reviewing the vast patent literature on its synthesis would be tedious. Instead, we will focus on the most notable cases of fluspirilene assembly from the relatively recent literature. For instance, an efficient synthesis of the key spirocyclic building block 30 needed for the synthesis of the drug was published in 2018 by a team of Italian and Polish scientists [14]. The synthesis commenced with 1-benzy piperidin-4-one, which was involved in the Strecker reaction with aniline and trimethylsilyl cyanide to give nitrile 31. The la er was hydrated in sulfuric acid and the resulting α-anilino carboxamide 32 was condensed with N,N-dimethylformamide dimethyl acetal to form spirocyclic imidazolinone 33. The C-N double bond in 33 was reduced to give imidazolidinone 34 and the benzyl group was removed by hydrogenation to give the target spirocycle 30 (Scheme 7). Fluspirilene is an old drug, and reviewing the vast patent literature on its synthesis would be tedious. Instead, we will focus on the most notable cases of fluspirilene assembly from the relatively recent literature. For instance, an efficient synthesis of the key spirocyclic building block 30 needed for the synthesis of the drug was published in 2018 by a team of Italian and Polish scientists [14]. The synthesis commenced with 1-benzyl piperidin-4-one, which was involved in the Strecker reaction with aniline and trimethylsilyl cyanide to give nitrile 31. The latter was hydrated in sulfuric acid and the resulting α-anilino carboxamide 32 was condensed with N,N-dimethylformamide dimethyl acetal to form spirocyclic imidazolinone 33. The C-N double bond in 33 was reduced to give imidazolidinone 34 and the benzyl group was removed by hydrogenation to give the target spirocycle 30 (Scheme 7). by a team of Italian and Polish scientists [14]. The synthesis commenced with 1-benzyl piperidin-4-one, which was involved in the Strecker reaction with aniline and trimethylsilyl cyanide to give nitrile 31. The la er was hydrated in sulfuric acid and the resulting α-anilino carboxamide 32 was condensed with N,N-dimethylformamide dimethyl acetal to form spirocyclic imidazolinone 33. The C-N double bond in 33 was reduced to give imidazolidinone 34 and the benzyl group was removed by hydrogenation to give the target spirocycle 30 (Scheme 7).

Scheme 7.
A 2018 synthesis of the core piperidine spirocycle needed for fluspirilene assembly.
Interestingly, it is the synthetic assembly of the 4,4-bis(4-fluorophenyl)butyl halide building block (for the alkylation of the key spirocycle 30) that received much of the synthetic route development. For instance, in 2001, an Italian group reported an interesting synthesis of fluspirilene, starting from 4,4′-difluorobenzophenone (35). Acetylene bis-lithium salt was added to the keto group of 35 in the presence of ethylene diamine to give allylic alcohol 36. The la er was hydroformylated in the presence of a rhodium catalysts cyclic hemiacetal 37. Sodium borohydride reduction of the la er furnished diol 38, which lost its doubly benzylic tertiary alcohol hydroxy group on hydrogenation. Alcohol 39 was brominated to alkyl halide 40, which then was used in the completion of fluspirilene synthesis (Scheme 8) [15]. Interestingly, it is the synthetic assembly of the 4,4-bis(4-fluorophenyl)butyl halide building block (for the alkylation of the key spirocycle 30) that received much of the synthetic route development. For instance, in 2001, an Italian group reported an interesting synthesis of fluspirilene, starting from 4,4 -difluorobenzophenone (35). Acetylene bislithium salt was added to the keto group of 35 in the presence of ethylene diamine to give allylic alcohol 36. The latter was hydroformylated in the presence of a rhodium catalysts cyclic hemiacetal 37. Sodium borohydride reduction of the latter furnished diol 38, which lost its doubly benzylic tertiary alcohol hydroxy group on hydrogenation. Alcohol 39 was brominated to alkyl halide 40, which then was used in the completion of fluspirilene synthesis (Scheme 8) [15]. A different approach to bromide 40 was reported in 2011 by a Shanghai Institute of Organic Chemistry group [16]. Diol 38 was obtained by reacting γ-butyrolactone with excess 4-fluorophenyl magnesium bromide. Thereupon, it was dehydrated in refluxing aqueous hydrochloric acid to give olefinic alcohol 41, the bromination of which gave  A different approach to bromide 40 was reported in 2011 by a Shanghai Institute of Organic Chemistry group [16]. Diol 38 was obtained by reacting γ-butyrolactone with excess 4-fluorophenyl magnesium bromide. Thereupon, it was dehydrated in refluxing aqueous hydrochloric acid to give olefinic alcohol 41, the bromination of which gave unsaturated alkyl bromide 42. Hydrogenation of the latter resulted in double bond saturation and went on without a loss of the bromide to give alkylating agent 40, which was used in the preparation of fluspirilene (Scheme 9).

Fenspiride
Fenspiride (Figure 4), a spirocyclic oxazolidinone, acting as an antagonist of a1adrenergic receptors, was first approved in selected European countries for medical use in the 1970s for the treatment of otolaryngological or ENT (ear, nose and throat) organ diseases, as well as respiratory tract diseases [17]. The structure of fenspiride comprises a well-established feature for binding to the hERG channel (an aromatic ring at a certain distance from a basic amine center) [18]. Unfortunately, it does bind to this off target, and causes prolongation of the QT interval. For this reason, i.e. the increased risk of torsades de pointes, fenspiride was withdrawn from the pharmaceutical market in most markets around the world [19]. One of the early patents, obtained by the Italian Voghera company for the synthesis of fenspiride, describes the assembly of the target molecule starting from 1-phenethyl piperidin-4-one (43), which was involved in the Reformatsky reaction with ethyl bromoacetate. After the conversion of the resulting β-hydroxy ester 44 to hydrazide 45, the la er was diazotized, which triggered a Curtius rearrangement of the intermediate acyl azide, and the isocyanate product of the rearrangement was trapped, intramolecularly, by the nearby hydroxy group, to give fenspiride (Scheme 10) [20].

Fenspiride
Fenspiride (Figure 4), a spirocyclic oxazolidinone, acting as an antagonist of a 1adrenergic receptors, was first approved in selected European countries for medical use in the 1970s for the treatment of otolaryngological or ENT (ear, nose and throat) organ diseases, as well as respiratory tract diseases [17]. The structure of fenspiride comprises a well-established feature for binding to the hERG channel (an aromatic ring at a certain distance from a basic amine center) [18]. Unfortunately, it does bind to this off target, and causes prolongation of the QT interval. For this reason, i.e. the increased risk of torsades de pointes, fenspiride was withdrawn from the pharmaceutical market in most markets around the world [19].

Fenspiride
Fenspiride (Figure 4), a spirocyclic oxazolidinone, acting as an antagonist of a1adrenergic receptors, was first approved in selected European countries for medical use in the 1970s for the treatment of otolaryngological or ENT (ear, nose and throat) organ diseases, as well as respiratory tract diseases [17]. The structure of fenspiride comprises a well-established feature for binding to the hERG channel (an aromatic ring at a certain distance from a basic amine center) [18]. Unfortunately, it does bind to this off target, and causes prolongation of the QT interval. For this reason, i.e. the increased risk of torsades de pointes, fenspiride was withdrawn from the pharmaceutical market in most markets around the world [19]. One of the early patents, obtained by the Italian Voghera company for the synthesis of fenspiride, describes the assembly of the target molecule starting from 1-phenethyl piperidin-4-one (43), which was involved in the Reformatsky reaction with ethyl bromoacetate. After the conversion of the resulting β-hydroxy ester 44 to hydrazide 45, the la er was diazotized, which triggered a Curtius rearrangement of the intermediate acyl azide, and the isocyanate product of the rearrangement was trapped, intramolecularly, by the nearby hydroxy group, to give fenspiride (Scheme 10) [20]. One of the early patents, obtained by the Italian Voghera company for the synthesis of fenspiride, describes the assembly of the target molecule starting from 1-phenethyl piperidin-4-one (43), which was involved in the Reformatsky reaction with ethyl bromoacetate. After the conversion of the resulting β-hydroxy ester 44 to hydrazide 45, the latter was diazotized, which triggered a Curtius rearrangement of the intermediate acyl azide, and the isocyanate product of the rearrangement was trapped, intramolecularly, by the nearby hydroxy group, to give fenspiride (Scheme 10) [20].
One of the early patents, obtained by the Italian Voghera company for the synthesis of fenspiride, describes the assembly of the target molecule starting from 1-phenethyl piperidin-4-one (43), which was involved in the Reformatsky reaction with ethyl bromoacetate. After the conversion of the resulting β-hydroxy ester 44 to hydrazide 45, the la er was diazotized, which triggered a Curtius rearrangement of the intermediate acyl azide, and the isocyanate product of the rearrangement was trapped, intramolecularly, by the nearby hydroxy group, to give fenspiride (Scheme 10) [20]. Scheme 10. Synthesis of fenspiride by the Voghera company [20].
In 1994, a Mexican group disclosed an alternative approach to elaborating the spirocyclic oxazolidinone based on 1-phenethyl piperidin-4-one, which includes the Streckertype reaction of the ketone with trimethylsilyl cyanide. The resulting O-silylated a-hydroxy nitrile 46 was subjected to reduction with lithium alumohydride to give β-amino alcohol 47. The latter was treated with trichloromethyl carbonate, which donated the carbonyl group and resulted in the closure of the oxazolidinone ring of fenspiride (Scheme 11) [21].
In 1994, a Mexican group disclosed an alternative approach to elaborating the spirocyclic oxazolidinone based on 1-phenethyl piperidin-4-one, which includes the Strecker-type reaction of the ketone with trimethylsilyl cyanide. The resulting O-silylated a-hydroxy nitrile 46 was subjected to reduction with lithium alumohydride to give βamino alcohol 47. The la er was treated with trichloromethyl carbonate, which donated the carbonyl group and resulted in the closure of the oxazolidinone ring of fenspiride (Scheme 11) [21].
Scheme 11. Synthesis of fenspiride by a Mexican group.
In 2019, the Indian company Emcure Pharmaceuticals jointly with a University of Pune group published a completely novel route to fenspiride which is based on the nitro aldol reaction and is amenable to industrial-scale production of the drug substance [22]. In fact, the researchers disclosed two possible approaches to fenspiride for comparison, and reached a conclusion that the nitro aldol route was preferred from the standpoint of pharmaceutical production. In the first approach, Corey-Chaykovsky epoxidation gave epoxide 48, which was opened up by sodium azide to give β-azido alcohol 49. Reduction by hydrazine (presumably to alcohol 47) and treatment with CDI (the donor of the carbonyl) afforded fenspiride. In the second, preferred, approach, ketone 43 was condensed with nitromethane anion and the resulting nitro compound 50 was reduced to the respective amine and Boc-protected to afford intermediate 51. Deprotonation of the hydroxy group in the la er with potassium tert-butoxide triggered intramolecular displacement of the tert-butoxy group and ring closure to fenspiride (Scheme 12). Additionally, the second route was performed on a large scale, starting with 1 kg of compound 50 to furnish 880 g of fenspiride.
It is worth noting the effective procedure for the late-stage [ 11 C], [ 13 C] and [ 14 C] carbon isotope labeling of cyclic carbamates recently developed by Audusio and co-workers [23]. The method allows the incorporation of labeled carbon dioxide into azidoalcohol 10 to furnish C-labeled fenspiride in a direct, cost-effective and sustainable manner. In 2019, the Indian company Emcure Pharmaceuticals jointly with a University of Pune group published a completely novel route to fenspiride which is based on the nitro aldol reaction and is amenable to industrial-scale production of the drug substance [22]. In fact, the researchers disclosed two possible approaches to fenspiride for comparison, and reached a conclusion that the nitro aldol route was preferred from the standpoint of pharmaceutical production. In the first approach, Corey-Chaykovsky epoxidation gave epoxide 48, which was opened up by sodium azide to give β-azido alcohol 49. Reduction by hydrazine (presumably to alcohol 47) and treatment with CDI (the donor of the carbonyl) afforded fenspiride. In the second, preferred, approach, ketone 43 was condensed with nitromethane anion and the resulting nitro compound 50 was reduced to the respective amine and Boc-protected to afford intermediate 51. Deprotonation of the hydroxy group in the latter with potassium tert-butoxide triggered intramolecular displacement of the tert-butoxy group and ring closure to fenspiride (Scheme 12). Additionally, the second route was performed on a large scale, starting with 1 kg of compound 50 to furnish 880 g of fenspiride.
It is worth noting the effective procedure for the late-stage [ 11 C], [ 13 C] and [ 14 C] carbon isotope labeling of cyclic carbamates recently developed by Audusio and co-workers [23]. The method allows the incorporation of labeled carbon dioxide into azidoalcohol 10 to furnish C-labeled fenspiride in a direct, cost-effective and sustainable manner. Scheme 12. Synthesis of fenspiride by Emcure Pharmaceuticals [22].

Amcinonide
Amcinonide ( Figure 5) is a topical corticosteroid approved in 1979 for the treatment of various inflammatory dermatological conditions such as atopic dermatitis and allergic contact dermatitis. Amcinonide displayed high affinity to the glucocorticoid receptor which is thought to be the main biological target mediating its anti-inflammatory action. Binding to the receptor and its activation by amcinonide eventually leads to the induction of phospholipase A2 inhibitory proteins, which suppresses the production of arachidonic acid and the downstream production of prostaglandins as chemical mediators of inflammation [24]. Unfortunately, synthetic routes to amcinonide are poorly described in the literature. Even the original patent issued to the American Cyanamide company [25] features li le synthetic detail. An industrial synthesis of amcinonide patented by an Indian company in 2018 [26] is described in sufficient detail. It starts with readily available natural steroid 2-((10S,13S,14S)-10,13-dimethyl-3-oxo-6,7,8,10,12,13,14,15-octahydro-3Hcyclopenta[a]phenanthren-17-yl)-2-oxoethyl acetate (52). The la er is subjected to epoxidation of the non-conjugated double bond using 1,3-dibromo-5,5dimethylhydantoin (dibromantin, 53) and aqueous perchloric acid, followed by the treatment of the resulting bromohydrin with potassium carbonate. Epoxide 54 is formed with high diastereoselectivity. The next step is dihydroxylation of the cyclopentene ring, which is brought about by potassium permanganate and formic acid in acetone. Finally, diol 55 is formed diastereoselectively, then subjected to the treatment with 70% hydrofluoric acid, followed by the addition of cyclopentanone. The net result of the la er step is epoxide opening with the fluoride anion and spirocyclic ketal formation leading to amcinonide (Scheme 13).

Amcinonide
Amcinonide ( Figure 5) is a topical corticosteroid approved in 1979 for the treatment of various inflammatory dermatological conditions such as atopic dermatitis and allergic contact dermatitis. Amcinonide displayed high affinity to the glucocorticoid receptor which is thought to be the main biological target mediating its anti-inflammatory action. Binding to the receptor and its activation by amcinonide eventually leads to the induction of phospholipase A2 inhibitory proteins, which suppresses the production of arachidonic acid and the downstream production of prostaglandins as chemical mediators of inflammation [24].

Amcinonide
Amcinonide ( Figure 5) is a topical corticosteroid approved in 1979 for the treatment of various inflammatory dermatological conditions such as atopic dermatitis and allergic contact dermatitis. Amcinonide displayed high affinity to the glucocorticoid receptor which is thought to be the main biological target mediating its anti-inflammatory action. Binding to the receptor and its activation by amcinonide eventually leads to the induction of phospholipase A2 inhibitory proteins, which suppresses the production of arachidonic acid and the downstream production of prostaglandins as chemical mediators of inflammation [24]. Unfortunately, synthetic routes to amcinonide are poorly described in the literature. Even the original patent issued to the American Cyanamide company [25] features li le synthetic detail. An industrial synthesis of amcinonide patented by an Indian company in 2018 [26] is described in sufficient detail. It starts with readily available natural steroid 2-((10S,13S,14S)-10,13-dimethyl-3-oxo-6,7,8,10,12,13,14,15-octahydro-3Hcyclopenta[a]phenanthren-17-yl)-2-oxoethyl acetate (52). The la er is subjected to epoxidation of the non-conjugated double bond using 1,3-dibromo-5,5dimethylhydantoin (dibromantin, 53) and aqueous perchloric acid, followed by the treatment of the resulting bromohydrin with potassium carbonate. Epoxide 54 is formed with high diastereoselectivity. The next step is dihydroxylation of the cyclopentene ring, which is brought about by potassium permanganate and formic acid in acetone. Finally, diol 55 is formed diastereoselectively, then subjected to the treatment with 70% hydrofluoric acid, followed by the addition of cyclopentanone. The net result of the la er step is epoxide opening with the fluoride anion and spirocyclic ketal formation leading to amcinonide (Scheme 13). Unfortunately, synthetic routes to amcinonide are poorly described in the literature. Even the original patent issued to the American Cyanamide company [25] features little synthetic detail. An industrial synthesis of amcinonide patented by an Indian company in 2018 [26] is described in sufficient detail. It starts with readily available natural steroid 2-((10S,13S,14S)-10,13-dimethyl-3-oxo-6,7,8,10,12,13,14,15-octahydro-3Hcyclopenta[a]phenanthren-17-yl)-2-oxoethyl acetate (52). The latter is subjected to epoxidation of the non-conjugated double bond using 1,3-dibromo-5,5-dimethylhydantoin (dibromantin, 53) and aqueous perchloric acid, followed by the treatment of the resulting bromohydrin with potassium carbonate. Epoxide 54 is formed with high diastereoselectivity. The next step is dihydroxylation of the cyclopentene ring, which is brought about by potassium permanganate and formic acid in acetone. Finally, diol 55 is formed diastereoselectively, then subjected to the treatment with 70% hydrofluoric acid, followed by the addition of cyclopentanone. The net result of the latter step is epoxide opening with the fluoride anion and spirocyclic ketal formation leading to amcinonide (Scheme 13).

Guanadrel
Guanadrel ( Figure 6) is an anti-hypertension drug containing a guanidine moiety which was approved in 1979 [27]. It exerts its therapeutic action by blocking the sodiumdependent noradrenaline transporter, and thus is a typical adrenoblocker [28]. The industrial synthesis of guanadrel was patented in 1970 by its inventors [29]. In the first step, cyclohexanone undergoes ketalization with 3-chloro-1,2-propandiol (56), forming 2chloromethyl-1,4-dioxyspiro [4,5] decane (57). The la er building block is used to alkylate phthalimide sodium salt to give the protected amine derivative 58. Removal of the phthalimide protecting group with hydrazine liberates the primary amino group in 59, which is reacted with S-methyl thiourea sulfate in aqueous medium on steam bath heating to give guanadrel as a sulfate salt (Scheme 14).

Guanadrel
Guanadrel ( Figure 6) is an anti-hypertension drug containing a guanidine moiety which was approved in 1979 [27]. It exerts its therapeutic action by blocking the sodiumdependent noradrenaline transporter, and thus is a typical adrenoblocker [28]. The industrial synthesis of guanadrel was patented in 1970 by its inventors [29]. In the first step, cyclohexanone undergoes ketalization with 3-chloro-1,2-propandiol (56), forming 2-chloromethyl-1,4-dioxyspiro [4,5]decane (57). The latter building block is used to alkylate phthalimide sodium salt to give the protected amine derivative 58. Removal of the phthalimide protecting group with hydrazine liberates the primary amino group in 59, which is reacted with S-methyl thiourea sulfate in aqueous medium on steam bath heating to give guanadrel as a sulfate salt (Scheme 14).

Guanadrel
Guanadrel ( Figure 6) is an anti-hypertension drug containing a guanidine moiety which was approved in 1979 [27]. It exerts its therapeutic action by blocking the sodiumdependent noradrenaline transporter, and thus is a typical adrenoblocker [28]. The industrial synthesis of guanadrel was patented in 1970 by its inventors [29]. In the first step, cyclohexanone undergoes ketalization with 3-chloro-1,2-propandiol (56), forming 2chloromethyl-1,4-dioxyspiro [4,5] decane (57). The la er building block is used to alkylate phthalimide sodium salt to give the protected amine derivative 58. Removal of the phthalimide protecting group with hydrazine liberates the primary amino group in 59, which is reacted with S-methyl thiourea sulfate in aqueous medium on steam bath heating to give guanadrel as a sulfate salt (Scheme 14).

Guanadrel
Guanadrel ( Figure 6) is an anti-hypertension drug containing a guanidine moiety which was approved in 1979 [27]. It exerts its therapeutic action by blocking the sodiumdependent noradrenaline transporter, and thus is a typical adrenoblocker [28]. The industrial synthesis of guanadrel was patented in 1970 by its inventors [29]. In the first step, cyclohexanone undergoes ketalization with 3-chloro-1,2-propandiol (56), forming 2chloromethyl-1,4-dioxyspiro [4,5] decane (57). The la er building block is used to alkylate phthalimide sodium salt to give the protected amine derivative 58. Removal of the phthalimide protecting group with hydrazine liberates the primary amino group in 59, which is reacted with S-methyl thiourea sulfate in aqueous medium on steam bath heating to give guanadrel as a sulfate salt (Scheme 14). In 1999, Goodman of UC San Diego developed a novel guanidine synthesis using triflyl-diurethane protected guanidines and applied it to the synthesis of guanadrel. In this synthesis, cyclohexanone was ketalized with acetylamino-substituted diol 60. The resulting spirocyclic building block 61 was deacetylated with hydrazine and reacted with N,N -di-Cbz-N"-triflylguanidine (62). Upon the displacement of the triflic amide, which is a leaving group in 62, bis-Cbz-protected guanidine 63 was hydrogenated over palladium on charcoal to give guanadrel in quantitative yield as a free base (Scheme 15). Interestingly, the attempted use of Boc protecting groups in lieu of Cbz failed, since the deprotection under acidic conditions led also to the removal of the acid-prone ketal [30]. In 1999, Goodman of UC San Diego developed a novel guanidine synthesis using triflyl-diurethane protected guanidines and applied it to the synthesis of guanadrel. In this synthesis, cyclohexanone was ketalized with acetylamino-substituted diol 60. The resulting spirocyclic building block 61 was deacetylated with hydrazine and reacted with N,N′-di-Cbz-N″-triflylguanidine (62). Upon the displacement of the triflic amide, which is a leaving group in 62, bis-Cbz-protected guanidine 63 was hydrogenated over palladium on charcoal to give guanadrel in quantitative yield as a free base (Scheme 15). Interestingly, the a empted use of Boc protecting groups in lieu of Cbz failed, since the deprotection under acidic conditions led also to the removal of the acid-prone ketal [30].

Buspirone
First synthesized in 1966 and approved for medical use in 1986 buspirone ( Figure 7), a spirocyclic serotonin 5-HT1A receptor agonist is primarily used to treat anxiety disorders [31]. Several patented protocols for the preparation of buspirone [32][33][34], including industrial synthesis, have been reported in the literature. On the plant scale, the following route was initially employed for the production of buspirone. 1-(Pyrimidin-2-yl)piperazine (64) was alkylated with 4-chlorobutyronitrile (65), and the nitrile group was hydrogenated over Raney nickel catalyst to give butylamine 66. The la er was condensed with commercially available 3,3-tetramethylene glutaric anhydride (67) in refluxing pyridine to give, after crystallization, buspirone [33] (Scheme 16).

Buspirone
First synthesized in 1966 and approved for medical use in 1986 buspirone ( Figure 7), a spirocyclic serotonin 5-HT 1A receptor agonist is primarily used to treat anxiety disorders [31]. Several patented protocols for the preparation of buspirone [32][33][34], including industrial synthesis, have been reported in the literature. In 1999, Goodman of UC San Diego developed a novel guanidine synthesis using triflyl-diurethane protected guanidines and applied it to the synthesis of guanadrel. In this synthesis, cyclohexanone was ketalized with acetylamino-substituted diol 60. The resulting spirocyclic building block 61 was deacetylated with hydrazine and reacted with N,N′-di-Cbz-N″-triflylguanidine (62). Upon the displacement of the triflic amide, which is a leaving group in 62, bis-Cbz-protected guanidine 63 was hydrogenated over palladium on charcoal to give guanadrel in quantitative yield as a free base (Scheme 15). Interestingly, the a empted use of Boc protecting groups in lieu of Cbz failed, since the deprotection under acidic conditions led also to the removal of the acid-prone ketal [30].
Over more than three decades following the approval of buspirone for medical use, several newer synthetic routes appeared in the literature journals, some of which will be discussed below.
In 2008, Wei and co-workers from China University of Mining and Technology reported a new process for the production of buspirone. In the first step, condensation of cyclopentanone with methyl isocyanoacetate catalyzed by ammonia followed by acidic ester hydrolysis afforded cyclopentane-1,1-diacetic acid (68). Heating of the latter with ammonium carbonate at 200 • C afforded 3,3-tetramethyleneglutarimide (69). The latter was alkylated with butyl bromide 70 which was prepared, in turn, from 1-(pyrimidin-2yl)piperazine (64) by alkylation with 1,4-dibromobutane. The last step afforded buspirone in nearly quantitative yield (Scheme 17) [35]. Over more than three decades following the approval of buspirone for medical use, several newer synthetic routes appeared in the literature journals, some of which will be discussed below.
In 2008, Wei and co-workers from China University of Mining and Technology reported a new process for the production of buspirone. In the first step, condensation of cyclopentanone with methyl isocyanoacetate catalyzed by ammonia followed by acidic ester hydrolysis afforded cyclopentane-1,1-diacetic acid (68). Heating of the la er with ammonium carbonate at 200 °C afforded 3,3-tetramethyleneglutarimide (69). The la er was alkylated with butyl bromide 70 which was prepared, in turn, from 1-(pyrimidin-2yl)piperazine (64) by alkylation with 1,4-dibromobutane. The last step afforded buspirone in nearly quantitative yield (Scheme 17) [35].  Over more than three decades following the approval of buspirone for medical use, several newer synthetic routes appeared in the literature journals, some of which will be discussed below.
In 2008, Wei and co-workers from China University of Mining and Technology reported a new process for the production of buspirone. In the first step, condensation of cyclopentanone with methyl isocyanoacetate catalyzed by ammonia followed by acidic ester hydrolysis afforded cyclopentane-1,1-diacetic acid (68). Heating of the la er with ammonium carbonate at 200 °C afforded 3,3-tetramethyleneglutarimide (69). The la er was alkylated with butyl bromide 70 which was prepared, in turn, from 1-(pyrimidin-2yl)piperazine (64) by alkylation with 1,4-dibromobutane. The last step afforded buspirone in nearly quantitative yield (Scheme 17) [35].
In 2019, Steven Ley and co-workers reported a continuous flow method to prepare buspirone which involves the direct alkylation of 1-(pyrimidin-2-yl)piperazine (64) with alcohol 71 via a Ru(II)-catalyzed hydrogen-borrowing approach (Scheme 18) [36]. In 2022, Beller and co-workers reported a remarkable, Ni-catalyzed reductive crosscoupling of nitriles with primary and secondary amines. In order to exemplify the scope of their methodology, a novel synthesis of buspirone was presented. Nitrile 72 prepared by alkylation of 3,3-tetramethylene glutarimide (69) with 4-bromobutyronitrile reacted 1-Scheme 18. Preparation of buspirone involving piperazine alkylation via hydrogen borrowing.
In 2022, Beller and co-workers reported a remarkable, Ni-catalyzed reductive crosscoupling of nitriles with primary and secondary amines. In order to exemplify the scope of their methodology, a novel synthesis of buspirone was presented. Nitrile 72 prepared by alkylation of 3,3-tetramethylene glutarimide (69) with 4-bromobutyronitrile reacted 1-(pyrimidin-2-yl)piperazine (64) under 40 bar of hydrogen in the presence of nickel triflate and a special triphosphine ligand to give 80% yield of buspirone (Scheme 19) [37].

Scheme 18. Preparation of buspirone involving piperazine alkylation via hydrogen borrowing
In 2022, Beller and co-workers reported a remarkable, Ni-catalyzed reductive cr coupling of nitriles with primary and secondary amines. In order to exemplify the sc of their methodology, a novel synthesis of buspirone was presented. Nitrile 72 prep by alkylation of 3,3-tetramethylene glutarimide (69) with 4-bromobutyronitrile reacte (pyrimidin-2-yl)piperazine (64) under 40 bar of hydrogen in the presence of nickel tri and a special triphosphine ligand to give 80% yield of buspirone (Scheme 19) [37].

Ivermectin
Discovered in 1975 ivermectin (Figure 8), an antiparasitic drug was initially approved for veterinary use in 1981. After extensive clinical research, ivermectin was approved in 1987 for use in humans, for the treatment for a wide range of parasitic infections [38,39]. Ivermectin acts by binding to parasites' glutamate-gated sodium channels and forcing them to remain open, which causes the overflow of chlorine anions and, consequently, hyperpolarization of the cell membranes. This eventually kills the parasite [40].
(pyrimidin-2-yl)piperazine (64) under 40 bar of hydrogen in the prese and a special triphosphine ligand to give 80% yield of buspirone (Sche  Ivermectin is an approximately 80:20 mixture of two individual macrocyclic lactone (macrolide) compounds, ivermectin B 1a and B 1b . These compounds are produced by hydrogenation of the C 22 = C 23 double bond of the mixture of avermectins B 1a and B 1b which are, in turn, produced by fermentation of Streptomyces avermitilis, the bacteria discovered in 1970 by SatoshiŌmura, for which discovery he and William Campbell of Merck were awarded the Nobel Prize in Physiology or Medicine [41]. In one of the more recent patents, Bayer described the hydrogenation of avermectins to ivermectins performed over the RhCl 3 ·H 2 O catalyst in the presence of triphenylphosphine (Scheme 20) [42]. In addition, several successful total syntheses of avermectin and ivermectin by academic research groups have been reported in the literature [43]. However, these syntheses are not economically viable for the production of the drug.
hydrogenation of the C 22 = C 23 double bond of the mixture of avermectins B1a and B1b which are, in turn, produced by fermentation of Streptomyces avermitilis, the bacteria discovered in 1970 by Satoshi Ōmura, for which discovery he and William Campbell of Merck were awarded the Nobel Prize in Physiology or Medicine [41]. In one of the more recent patents, Bayer described the hydrogenation of avermectins to ivermectins performed over the RhCl3·H2O catalyst in the presence of triphenylphosphine (Scheme 20) [42]. In addition, several successful total syntheses of avermectin and ivermectin by academic research groups have been reported in the literature [43]. However, these syntheses are not economically viable for the production of the drug. Scheme 20. Hydrogenation of avermectins B1a and B1b.

Rifabutin
Rifabutin (Figure 9), a macrocyclic semisynthetic drug of the rifamycin family [44] was developed by the Italian drug company Farmitalia Carlo Erba, and received FDA approval in 1992 for the treatment of tuberculosis, as well as other bacterial infections such as Mycobacterium avium complex [45]. The drug works via the inhibition of the DNAdependent RNA polymerase in bacteria, leading to a suppression of RNA synthesis and cell death [46]. The original synthesis of rifabutin was reported by Marsili and colleagues from Framitalia in 1981 [47]. The synthesis relied on 3-aminorifamycin S (73) prepared via azidation of rifamycin S (74), which was accompanied by a spontaneous loss of nitrogen molecule [48]. Compound 73 was treated with ammonia solution in THF to give 3-amino-4-deoxo-4-iminorifamycin S (75). The la er was isolated by crystallization and further involved in cyclocondensation with N-isobutyl piperidone, performed at ambient temperature in the presence of ammonium acetate as a mild acidic catalyst. As a result, a Scheme 20. Hydrogenation of avermectins B 1a and B 1b .

Rifabutin
Rifabutin (Figure 9), a macrocyclic semisynthetic drug of the rifamycin family [44] was developed by the Italian drug company Farmitalia Carlo Erba, and received FDA approval in 1992 for the treatment of tuberculosis, as well as other bacterial infections such as Mycobacterium avium complex [45]. The drug works via the inhibition of the DNAdependent RNA polymerase in bacteria, leading to a suppression of RNA synthesis and cell death [46]. economically viable for the production of the drug.

Rifabutin
Rifabutin (Figure 9), a macrocyclic semisynthetic drug of the ri was developed by the Italian drug company Farmitalia Carlo Erba, approval in 1992 for the treatment of tuberculosis, as well as other bact as Mycobacterium avium complex [45]. The drug works via the inhi dependent RNA polymerase in bacteria, leading to a suppression of cell death [46]. The original synthesis of rifabutin was reported by Marsili an Framitalia in 1981 [47]. The synthesis relied on 3-aminorifamycin S azidation of rifamycin S (74), which was accompanied by a spontane molecule [48]. Compound 73 was treated with ammonia solution in T 4-deoxo-4-iminorifamycin S (75). The la er was isolated by crystall involved in cyclocondensation with N-isobutyl piperidone, perf temperature in the presence of ammonium acetate as a mild acidic ca The original synthesis of rifabutin was reported by Marsili and colleagues from Framitalia in 1981 [47]. The synthesis relied on 3-aminorifamycin S (73) prepared via azidation of rifamycin S (74), which was accompanied by a spontaneous loss of nitrogen molecule [48]. Compound 73 was treated with ammonia solution in THF to give 3-amino-4-deoxo-4iminorifamycin S (75). The latter was isolated by crystallization and further involved in cyclocondensation with N-isobutyl piperidone, performed at ambient temperature in the presence of ammonium acetate as a mild acidic catalyst. As a result, a spirocyclic imidazoline moiety was installed, and pure rifabutin was isolated without chromatographic purification (Scheme 21).

Spirapril
Spirapril ( Figure 10), a spirocyclic inhibitor of the angiotensin-converting enzyme (ACE) had been originated and developed by the Schering-Plough Corporation (now Merck & Co.) and was approved in 1995 for the treatment of hypertension. ACE is a part of the renin-angiotensin system regulating blood pressure. Inhibition of ACE suppresses the production of the potent vasoconstrictor angiotensin II from its inactive precursor proangiotensin and thus prevents the increase in blood pressure [49]. Spirapril is an ethyl ester prodrug. It undergoes biotransformation to the respective carboxylic acid, spiraprilat, which is the active ACE inhibitor [50]. Several syntheses of spirapril have been reported in the patent and periodic literature around the time of the drug's approval. The original Schering-Plough route was patented in 1984 [51] and later disclosed in greater detail and with a few reaction sequence variants in a 1989 research article [52]. The synthesis commenced with Cbz-protected 4-oxoproline methyl ester (76), the carbonyl group of which was protected as spirocyclic thioketal, to give methyl ester 77. The Cbz group was removed by 20% hydrobromic acid in glacial acetic acid, to give amino acid 78. The ester side chain building block was prepared by reductive amination of the keto ester 79. The resulting amino acid 80 was obtained as a mixture of diastereomers. Without separation, the mixture was activated as Nhydroxysuccinimide ester (81) and reacted with 78 in the presence of triethylamine, to give a good yield of spirapril after diastereomer separation (Scheme 22).

Spirapril
Spirapril ( Figure 10), a spirocyclic inhibitor of the angiotensin-converting enzyme (ACE) had been originated and developed by the Schering-Plough Corporation (now Merck & Co.) and was approved in 1995 for the treatment of hypertension. ACE is a part of the renin-angiotensin system regulating blood pressure. Inhibition of ACE suppresses the production of the potent vasoconstrictor angiotensin II from its inactive precursor proangiotensin and thus prevents the increase in blood pressure [49]. Spirapril is an ethyl ester prodrug. It undergoes biotransformation to the respective carboxylic acid, spiraprilat, which is the active ACE inhibitor [50].

Spirapril
Spirapril ( Figure 10), a spirocyclic inhibitor of the angiotensin-converting enzyme (ACE) had been originated and developed by the Schering-Plough Corporation (now Merck & Co.) and was approved in 1995 for the treatment of hypertension. ACE is a part of the renin-angiotensin system regulating blood pressure. Inhibition of ACE suppresses the production of the potent vasoconstrictor angiotensin II from its inactive precursor proangiotensin and thus prevents the increase in blood pressure [49]. Spirapril is an ethyl ester prodrug. It undergoes biotransformation to the respective carboxylic acid, spiraprilat, which is the active ACE inhibitor [50]. Several syntheses of spirapril have been reported in the patent and periodic literature around the time of the drug's approval. The original Schering-Plough route was patented in 1984 [51] and later disclosed in greater detail and with a few reaction sequence variants in a 1989 research article [52]. The synthesis commenced with Cbz-protected 4-oxoproline methyl ester (76), the carbonyl group of which was protected as spirocyclic thioketal, to give methyl ester 77. The Cbz group was removed by 20% hydrobromic acid in glacial acetic acid, to give amino acid 78. The ester side chain building block was prepared by reductive amination of the keto ester 79. The resulting amino acid 80 was obtained as a mixture of diastereomers. Without separation, the mixture was activated as Nhydroxysuccinimide ester (81) and reacted with 78 in the presence of triethylamine, to give a good yield of spirapril after diastereomer separation (Scheme 22). Several syntheses of spirapril have been reported in the patent and periodic literature around the time of the drug's approval. The original Schering-Plough route was patented in 1984 [51] and later disclosed in greater detail and with a few reaction sequence variants in a 1989 research article [52]. The synthesis commenced with Cbz-protected 4-oxoproline methyl ester (76), the carbonyl group of which was protected as spirocyclic thioketal, to give methyl ester 77. The Cbz group was removed by 20% hydrobromic acid in glacial acetic acid, to give amino acid 78. The ester side chain building block was prepared by reductive amination of the keto ester 79. The resulting amino acid 80 was obtained as a mixture of diastereomers. Without separation, the mixture was activated as N-hydroxysuccinimide ester (81) and reacted with 78 in the presence of triethylamine, to give a good yield of spirapril after diastereomer separation (Scheme 22).
An alternative synthesis reported by the Squibb Corporation (now Bristol Myers Squibb) in 1988 also made use of spirocyclic amino acid 78. The latter was Boc-protected and the carboxylic function was esterified with 2-(trimethylsilyl)ethanol in the presence of DCC and DMAP to give good yield of ester 82. The Boc group was then removed by p-toluenesulfonic acid (PTSA) and the liberated free pyrrolidine 83 was acylated with carboxylic acid 80 activated by DCC/HOBt. This two-step sequence gave ester 84 in 70% after diastereomer separation. The removal of the 2-(trimethylsilyl)ethyl group with tetrabutylammonium fluoride trihydrate gave spiropril in quantitative yield (Scheme 23) [53]. An alternative synthesis reported by the Squibb Corporation (now Bristol Myers Squibb) in 1988 also made use of spirocyclic amino acid 78. The la er was Boc-protected and the carboxylic function was esterified with 2-(trimethylsilyl)ethanol in the presence o DCC and DMAP to give good yield of ester 82. The Boc group was then removed by p toluenesulfonic acid (PTSA) and the liberated free pyrrolidine 83 was acylated with carboxylic acid 80 activated by DCC/HOBt. This two-step sequence gave ester 84 in 70% after diastereomer separation. The removal of the 2-(trimethylsilyl)ethyl group with tetrabutylammonium fluoride trihydrate gave spiropril in quantitative yield (Scheme 23 [53]. [51].

Irbesartan
Irbesartan (Figure 11), a spirocyclic antihypertensive drug was developed by Sanofi Research (now Sanofi-Aventis) and approved for medical use in 1997. The compound is a typical representative of the sartan family of hypertensives, which act by blocking the angiotensin type 1 (AT1) receptor and preventing its activation and downstream events

Irbesartan
Irbesartan ( Figure 11), a spirocyclic antihypertensive drug was developed by Sanofi Research (now Sanofi-Aventis) and approved for medical use in 1997. The compound is a typical representative of the sartan family of hypertensives, which act by blocking the angiotensin type 1 (AT 1 ) receptor and preventing its activation and downstream events leading the blood pressure increase [54]. Irbesartan possesses four key elements of structure which are typical of sartans and could be traced back to losartan, the first-in-class AT 1 receptor blocker: biphenyl substituted with tetrazole in the ortho position of the distal ring, five-membered nitrogen heterocycle (in this case, imidazoline-5-one) and an n-butyl side chain [55].

Irbesartan
Irbesartan ( Figure 11), a spirocyclic antihypertensive drug was developed by Sanofi Research (now Sanofi-Aventis) and approved for medical use in 1997. The compound is a typical representative of the sartan family of hypertensives, which act by blocking the angiotensin type 1 (AT1) receptor and preventing its activation and downstream events leading the blood pressure increase [54]. Irbesartan possesses four key elements of structure which are typical of sartans and could be traced back to losartan, the first-inclass AT1 receptor blocker: biphenyl substituted with tetrazole in the ortho position of the distal ring, five-membered nitrogen heterocycle (in this case, imidazoline-5-one) and an n-butyl side chain [55]. The original synthetic route to irbesartan was described in detail in 1995 publication by Bernhart and co-workers (Sanofi Research) [56]. The synthesis relies on commercially available tetramethylene glycine ethyl ester (85) as the starting material. Amino ester 85 was condensed with imidate 86 in the presence of a catalytic amount of acetic acid in The original synthetic route to irbesartan was described in detail in 1995 publication by Bernhart and co-workers (Sanofi Research) [56]. The synthesis relies on commercially available tetramethylene glycine ethyl ester (85)   Interestingly, the key spirocyclic imidazolin-5-one building block 87 was recently accessed by Wu and DiPoto via a novel annulation of azaoxyallyl cations. Cyclopentanoyl chloride was first transformed into O-benzyl hydroxamic acid 89. The latter was treated with the base to generate azaoxyallyl cation 90, which reacted with pentanenitrile to give benzyloxy-substituted imidazolin-5-one 91. N-Deoxygenation with samarium iodide gave 87, thereby completing the formal synthesis of irbesartan (Scheme 25) [57].
Interestingly, the key spirocyclic imidazolin-5-one building block 87 was recently accessed by Wu and DiPoto via a novel annulation of azaoxyallyl cations. Cyclopentanoyl chloride was first transformed into O-benzyl hydroxamic acid 89. The la er was treated with the base to generate azaoxyallyl cation 90, which reacted with pentanenitrile to give benzyloxy-substituted imidazolin-5-one 91. N-Deoxygenation with samarium iodide gave 87, thereby completing the formal synthesis of irbesartan (Scheme 25) [57].
Scheme 25. Synthesis of key building block 87.
Intermediate 87 was also key in the synthesis of irbesartan patented by a group of Israeli scientists in 2004 [58]. The convergent route started with C-phenyl tetrazole (92) Among the synthetic routes to irbesartan featured in the patent literature, t following synthesis from Dr. Reddy's Laboratories is notable. Similarly to the Sanofi rou (vide supra), the synthesis started with tetramethylene glycine (96), which was acylat with pentanoyl chloride under phase transfer conditions to give carboxylic acid 97 whi in turn, was amidated with 4′-(aminomethyl)-[1,1′-biphenyl]-2-carbonitrile to give t 'fully decorated' precursor 98. The la er was cyclodehydrated in refluxing toluene in t presence of trifluoroacetic acid, to give nitrile 88 and, after [3 + 2] cycloaddition w tributyltin azide, irbesartan (Scheme 27) [59]. Among the synthetic routes to irbesartan featured in the patent literature, the following synthesis from Dr. Reddy's Laboratories is notable. Similarly to the Sanofi route (vide supra), the synthesis started with tetramethylene glycine (96), which was acylated with pentanoyl chloride under phase transfer conditions to give carboxylic acid 97 which, in turn, was amidated with 4 -(aminomethyl)-[1,1 -biphenyl]-2-carbonitrile to give the 'fully decorated' precursor 98. The latter was cyclodehydrated in refluxing toluene in the presence of trifluoroacetic acid, to give nitrile 88 and, after [3 + 2] cycloaddition with tributyltin azide, irbesartan (Scheme 27) [59].
following synthesis from Dr. Reddy's Laboratories is notable. Similarly to the Sanofi route (vide supra), the synthesis started with tetramethylene glycine (96), which was acylated with pentanoyl chloride under phase transfer conditions to give carboxylic acid 97 which, in turn, was amidated with 4′-(aminomethyl)-[1,1′-biphenyl]-2-carbonitrile to give the 'fully decorated' precursor 98. The la er was cyclodehydrated in refluxing toluene in the presence of trifluoroacetic acid, to give nitrile 88 and, after [3 + 2] cycloaddition with tributyltin azide, irbesartan (Scheme 27) [59]. Finally, a fundamentally different approach to irbesartan was developed in 2022 at Beijing University of Chemical Technology [61]. In this route, the spirocyclic scaffold of the drug was elaborated at a more advanced stage of the synthesis, as shown in Scheme 29. Glycine methyl ester was acylated by pentanoyl chloride and ester 99 was amidated with 4′-(aminomethyl)-[1,1′-biphenyl]-2-carbonitrile under forcing, base-promoted conditions, to give diamide 100. The la er was cyclodehydrated in refluxing toluene in the presence of methanesulfonic acid to give intermediate 101, which was found to be sufficiently C-H acidic to be doubly alkylated with 1,4-dibromobutane to furnish spirocyclic imidazoline-5-one 88. Notably, the nitrile-to-tetrazole conversion was achieved without the use of the toxic tin reagent (used in all previously described syntheses), which makes this 2022 route quite environmentally friendly and amenable to the plant-scale production of the drug. Finally, a fundamentally different approach to irbesartan was developed in 2022 at Beijing University of Chemical Technology [61]. In this route, the spirocyclic scaffold of the drug was elaborated at a more advanced stage of the synthesis, as shown in Scheme 29. Glycine methyl ester was acylated by pentanoyl chloride and ester 99 was amidated with 4 -(aminomethyl)-[1,1 -biphenyl]-2-carbonitrile under forcing, base-promoted conditions, to give diamide 100. The latter was cyclodehydrated in refluxing toluene in the presence of methanesulfonic acid to give intermediate 101, which was found to be sufficiently C-H acidic to be doubly alkylated with 1,4-dibromobutane to furnish spirocyclic imidazoline-5-one 88. Notably, the nitrile-to-tetrazole conversion was achieved without the use of the toxic tin reagent (used in all previously described syntheses), which makes this 2022 route quite environmentally friendly and amenable to the plant-scale production of the drug. the drug was elaborated at a more advanced stage of the synthesis, as shown in Scheme 29. Glycine methyl ester was acylated by pentanoyl chloride and ester 99 was amidated with 4′-(aminomethyl)-[1,1′-biphenyl]-2-carbonitrile under forcing, base-promoted conditions, to give diamide 100. The la er was cyclodehydrated in refluxing toluene in the presence of methanesulfonic acid to give intermediate 101, which was found to be sufficiently C-H acidic to be doubly alkylated with 1,4-dibromobutane to furnish spirocyclic imidazoline-5-one 88. Notably, the nitrile-to-tetrazole conversion was achieved without the use of the toxic tin reagent (used in all previously described syntheses), which makes this 2022 route quite environmentally friendly and amenable to the plant-scale production of the drug.

Scheme 29.
Beijing University of Chemical Technology route to irbesartan. Scheme 29. Beijing University of Chemical Technology route to irbesartan.

Cevimeline
Cevimelin (Figure 12), a spirocyclic derivative of quinuclidine acts as an agonist of muscarinic M 1 and M 3 receptors [62]. Originating from the Israel Institute of Biological Research, the drug was developed by the Daiichi Sankyo company and gained regulatory approval in 2000 for the treatment of dry mouth and Sjögren's syndrome [63]. Recently, the drug has been investigated in such therapeutic areas as cognitive impairment and neurodegenerative diseases [64].

Cevimeline
Cevimelin (Figure 12), a spirocyclic derivative of quinuclidine a muscarinic M1 and M3 receptors [62]. Originating from the Israel In Research, the drug was developed by the Daiichi Sankyo company an approval in 2000 for the treatment of dry mouth and Sjögren's syndr the drug has been investigated in such therapeutic areas as cogniti neurodegenerative diseases [64]. In the original synthesis of cevimeline patented by the commercially available quinuclidin-3-one was converted to epoxide 1 Chaykovsky reaction with trimethyloxosulfonium iodide (Me3S + hydride. The resulting epoxide 102 was treated with hydrogen sulfid medium, which led to epoxide opening and the formation of hydroxy was subjected to thio/oxa acetal formation on treatment with acetaldeh of boron trifluoride etherate. Cevimeline contained in the diaster products 104 was separated by fractional crystallization (Scheme 3 presented a rather elaborate scheme for the fractional crystallization. In the original synthesis of cevimeline patented by the Israeli group [65], commercially available quinuclidin-3-one was converted to epoxide 102 using the Corey-Chaykovsky reaction with trimethyloxosulfonium iodide (Me 3 S + (O)I − ) and sodium hydride. The resulting epoxide 102 was treated with hydrogen sulfide in a basic aqueous medium, which led to epoxide opening and the formation of hydroxy thiol 103. The latter was subjected to thio/oxa acetal formation on treatment with acetaldehyde in the presence of boron trifluoride etherate. Cevimeline contained in the diastereomeric mixture of products 104 was separated by fractional crystallization (Scheme 30). The patent [65] presented a rather elaborate scheme for the fractional crystallization.
In 2008, the Canadian company Apotex Pharmachem, Inc. filed a patent application for an improved synthesis of cevimeline which is similar in spirit to the original Israeli route. The Corey-Chaykovsky epoxidation of quinuclidine-3-one was performed with potassium tert-butoxide, and the opening of epoxide 102 was achieved with thioacetic acid in lieu of hydrogen sulfide gas. Thioacetate 105 was condensed directly with acetaldehyde dimethyl acetal, which gave an excellent yield of the diastereomeric mixture 104, from which cevimeline was isolated by diastereomer separation (Scheme 31) [66].
Chaykovsky reaction with trimethyloxosulfonium iodide (Me3S + (O)I − ) and sodium hydride. The resulting epoxide 102 was treated with hydrogen sulfide in a basic aqueous medium, which led to epoxide opening and the formation of hydroxy thiol 103. The la er was subjected to thio/oxa acetal formation on treatment with acetaldehyde in the presence of boron trifluoride etherate. Cevimeline contained in the diastereomeric mixture of products 104 was separated by fractional crystallization (Scheme 30). The patent [65] presented a rather elaborate scheme for the fractional crystallization.
In 2008, the Canadian company Apotex Pharmachem, Inc. filed a patent application for an improved synthesis of cevimeline which is similar in spirit to the original Israeli route. The Corey-Chaykovsky epoxidation of quinuclidine-3-one was performed with potassium tert-butoxide, and the opening of epoxide 102 was achieved with thioacetic acid in lieu of hydrogen sulfide gas. Thioacetate 105 was condensed directly with acetaldehyde dimethyl acetal, which gave an excellent yield of the diastereomeric mixture 104, from which cevimeline was isolated by diastereomer separation (Scheme 31) [66]. Scheme 31. Cevimeline synthesis by Apotex Pharmachem, Inc [66].
In 2013, the Active Pharmaceutical Ingredient R&D Center of the Indian company Emcure Pharmaceuticals, Ltd. published an even further improved route to cevimeline, in which safe and odorless thiourea is utilized as a thiolating reagent. Epoxide 102 was first converted to hydroxy bromide 106, which was then refluxed with thiourea in an aqueous medium to furnish thiolactone 107. The la er was hydrolyzed with aqueous sodium hydroxide to give the key hydroxy thiol 103, which was converted to cevimeline using the same routine as was developed in the original synthesis (vide supra) (Scheme 32) [67].
An intriguing, stand-alone approach to enantiomerically pure hydroxy thiol (S)-103 was published by F. Hoffmann-La Roche, Ltd. six years prior to the approval of cevimeline for medical use [68]. In this synthesis, the quinuclidine nucleus was elaborated quite late into the synthetic route. The synthesis relied on olefin 108 synthesized from pyridine-4carboxaldehyde in a few trivial steps. Sharpless epoxidation gave enantiomerically pure (ee 94%) epoxide 109, which was opened with benzyl mercaptan to give diol 110. Mesylation of the primary hydroxy group set the scene for the intramolecular SN2 reaction to form the quinuclidine core. This was achieved by the removal of the Boc group from Scheme 31. Cevimeline synthesis by Apotex Pharmachem, Inc. [66].
In 2013, the Active Pharmaceutical Ingredient R&D Center of the Indian company Emcure Pharmaceuticals, Ltd. published an even further improved route to cevimeline, in which safe and odorless thiourea is utilized as a thiolating reagent. Epoxide 102 was first converted to hydroxy bromide 106, which was then refluxed with thiourea in an aqueous medium to furnish thiolactone 107. The latter was hydrolyzed with aqueous sodium hydroxide to give the key hydroxy thiol 103, which was converted to cevimeline using the same routine as was developed in the original synthesis (vide supra) (Scheme 32) [67]. In 2013, the Active Pharmaceutical Ingredient R&D Center of the Indian compan Emcure Pharmaceuticals, Ltd. published an even further improved route to cevimeline, i which safe and odorless thiourea is utilized as a thiolating reagent. Epoxide 102 was fir converted to hydroxy bromide 106, which was then refluxed with thiourea in an aqueou medium to furnish thiolactone 107. The la er was hydrolyzed with aqueous sodium hydroxide to give the key hydroxy thiol 103, which was converted to cevimeline using th same routine as was developed in the original synthesis (vide supra) (Scheme 32) [67]. An intriguing, stand-alone approach to enantiomerically pure hydroxy thiol (S)-10 was published by F. Hoffmann-La Roche, Ltd. six years prior to the approval of cevimelin for medical use [68]. In this synthesis, the quinuclidine nucleus was elaborated quite la into the synthetic route. The synthesis relied on olefin 108 synthesized from pyridine-4 carboxaldehyde in a few trivial steps. Sharpless epoxidation gave enantiomerically pur (ee 94%) epoxide 109, which was opened with benzyl mercaptan to give diol 11 Mesylation of the primary hydroxy group set the scene for the intramolecular SN2 reactio to form the quinuclidine core. This was achieved by the removal of the Boc group from the piperidine nitrogen atom in 111 and by triggering the nucleophilic substitution b DIPEA. The bnzyl group was removed from intermediate 112 by dissolving the metal (Ca An intriguing, stand-alone approach to enantiomerically pure hydroxy thiol (S)-103 was published by F. Hoffmann-La Roche, Ltd. six years prior to the approval of cevimeline for medical use [68]. In this synthesis, the quinuclidine nucleus was elaborated quite late into the synthetic route. The synthesis relied on olefin 108 synthesized from pyridine-4-carboxaldehyde in a few trivial steps. Sharpless epoxidation gave enantiomerically pure (ee 94%) epoxide 109, which was opened with benzyl mercaptan to give diol 110.
Mesylation of the primary hydroxy group set the scene for the intramolecular S N 2 reaction to form the quinuclidine core. This was achieved by the removal of the Boc group from the piperidine nitrogen atom in 111 and by triggering the nucleophilic substitution by DIPEA. The bnzyl group was removed from intermediate 112 by dissolving the metal (Ca) reduction in ammonia (Scheme 33).

Eplerenone
Eplerenone (Figure 13), a spirocyclic antagonist of mineralocorticoid receptors developed by Ciba-Geigy was approved in 2002 for the treatment of hypertension and heart failure [69]. It is related to spironolactone but displays be er selectivity to its primary target through the affinity to androgen, progestogen, glucocorticoid, or estrogen receptors and thus is devoid of undesired sexual side effects typical of spironolactone, which limit its use [70]. Among industrial syntheses of eplerenone, the route patented in 1998 by Searle & Co. is quite notable [71]. The synthesis starts with steroid intermediate 20 (also useful in the synthesis of spironolactone, vide supra) which is subjected to regiospecific and stereoselective hydroxylation by fermentation with the Aspergillus ochraceus mold. The hydroxy group in 113 serves as a kind of masked double bond which is unmasked later in the synthesis. Condensation with two equivalents of cyanide (in the form of acetone cyanohydrin) results in the formation of polycyclic enamine 114. The la er is hydrolyzed to ketone 115, which is then put through a sequence of steps including treatment with sodium methoxide (opening the ketone linkage as the methyl ester with simultaneous elimination of the cyanide), mesylation of the hydroxy group, and elimination of methane sulfonic acid to give the olefinic intermediate 116. The la er is epoxidized on treatment with hydrogen peroxide in a phosphate buffered solution, to give eplerenone (Scheme 34).

Eplerenone
Eplerenone (Figure 13), a spirocyclic antagonist of mineralocorticoid receptors developed by Ciba-Geigy was approved in 2002 for the treatment of hypertension and heart failure [69]. It is related to spironolactone but displays better selectivity to its primary target through the affinity to androgen, progestogen, glucocorticoid, or estrogen receptors and thus is devoid of undesired sexual side effects typical of spironolactone, which limit its use [70].

Eplerenone
Eplerenone (Figure 13), a spirocyclic antagonist of mineralocorticoid receptors developed by Ciba-Geigy was approved in 2002 for the treatment of hypertension and heart failure [69]. It is related to spironolactone but displays be er selectivity to its primary target through the affinity to androgen, progestogen, glucocorticoid, or estrogen receptors and thus is devoid of undesired sexual side effects typical of spironolactone, which limit its use [70]. Among industrial syntheses of eplerenone, the route patented in 1998 by Searle & Co. is quite notable [71]. The synthesis starts with steroid intermediate 20 (also useful in the synthesis of spironolactone, vide supra) which is subjected to regiospecific and stereoselective hydroxylation by fermentation with the Aspergillus ochraceus mold. The hydroxy group in 113 serves as a kind of masked double bond which is unmasked later in the synthesis. Condensation with two equivalents of cyanide (in the form of acetone cyanohydrin) results in the formation of polycyclic enamine 114. The la er is hydrolyzed to ketone 115, which is then put through a sequence of steps including treatment with sodium methoxide (opening the ketone linkage as the methyl ester with simultaneous elimination of the cyanide), mesylation of the hydroxy group, and elimination of methane sulfonic acid to give the olefinic intermediate 116. The la er is epoxidized on treatment with hydrogen peroxide in a phosphate buffered solution, to give eplerenone (Scheme 34).   An interesting eplerenone synthesis was published in 2006 by Pfizer's process chemistry team [73]. The synthesis commences with the same spirocyclic lactone 117 as was employed by Ciba-Geigy (vide supra). 2-Methylfuran was employed as a chemical equivalent of the carboxylic group. On Lewis acid catalysis, it underwent arylation of the distal conjugated double bond. The furan moiety in 121 was hydrolyzed to enedione 122 and the la er, without isolation, was ozonolyzed to give the hemiacetal 123. The la er was subjected to Beyer-Villiger oxidation, to give carboxylic acid 124, which was forced to close to isolable bis-lactone 125. The strained lactone in 125 was opened up via elimination and the intermediate carboxylic acid was esterified with methyl sulfate to give ester 116. The la er is only one epoxidation step away from eplerenone (Scheme 36).   An interesting eplerenone synthesis was published in 2006 by Pfizer's process chemistry team [73]. The synthesis commences with the same spirocyclic lactone 117 as was employed by Ciba-Geigy (vide supra). 2-Methylfuran was employed as a chemical equivalent of the carboxylic group. On Lewis acid catalysis, it underwent arylation of the distal conjugated double bond. The furan moiety in 121 was hydrolyzed to enedione 122 and the la er, without isolation, was ozonolyzed to give the hemiacetal 123. The la er was subjected to Beyer-Villiger oxidation, to give carboxylic acid 124, which was forced to close to isolable bis-lactone 125. The strained lactone in 125 was opened up via elimination and the intermediate carboxylic acid was esterified with methyl sulfate to give ester 116. The la er is only one epoxidation step away from eplerenone (Scheme 36).

Scheme 35. Synthesis of eplerenone by Ciba-Geigy [72].
An interesting eplerenone synthesis was published in 2006 by Pfizer's process chemistry team [73]. The synthesis commences with the same spirocyclic lactone 117 as was employed by Ciba-Geigy (vide supra). 2-Methylfuran was employed as a chemical equivalent of the carboxylic group. On Lewis acid catalysis, it underwent arylation of the distal conjugated double bond. The furan moiety in 121 was hydrolyzed to enedione 122 and the latter, without isolation, was ozonolyzed to give the hemiacetal 123. The latter was subjected to Beyer-Villiger oxidation, to give carboxylic acid 124, which was forced to close to isolable bis-lactone 125. The strained lactone in 125 was opened up via elimination and the intermediate carboxylic acid was esterified with methyl sulfate to give ester 116. The latter is only one epoxidation step away from eplerenone (Scheme 36).

Scheme 36. Synthesis of eplerenone by Pfizer [73].
Intermediate 125 is clearly key to the large-scale synthesis of eplerenone. In 2011, a Chinese Academy of Sciences group published an interesting approach to it from triene 117, which involves the conjugate addition of silyl methyl cuprate, Tamao oxidation and another intramolecular oxa-Michael addition, to give cyclic ether 126. Curiously, methyltrifluoromethyl dioxirane was found to selectively oxidize ether 126 to lactol 127. PDC oxidation of the la er gave a nearly quantitative yield of lactone 125, which could now be opened and epoxidized to eplerenone as described by Pfizer (vide supra) (Scheme 37) [74].
Scheme 37. Synthesis of eplerenone by Chinese Academy of Sciences [74]. Intermediate 125 is clearly key to the large-scale synthesis of eplerenone. In 2011, a Chinese Academy of Sciences group published an interesting approach to it from triene 117, which involves the conjugate addition of silyl methyl cuprate, Tamao oxidation and another intramolecular oxa-Michael addition, to give cyclic ether 126. Curiously, methyltrifluoromethyl dioxirane was found to selectively oxidize ether 126 to lactol 127. PDC oxidation of the latter gave a nearly quantitative yield of lactone 125, which could now be opened and epoxidized to eplerenone as described by Pfizer (vide supra) (Scheme 37) [74]. Intermediate 125 is clearly key to the large-scale synthesis of eplerenone. In 2011, a Chinese Academy of Sciences group published an interesting approach to it from triene 117, which involves the conjugate addition of silyl methyl cuprate, Tamao oxidation and another intramolecular oxa-Michael addition, to give cyclic ether 126. Curiously, methyltrifluoromethyl dioxirane was found to selectively oxidize ether 126 to lactol 127. PDC oxidation of the la er gave a nearly quantitative yield of lactone 125, which could now be opened and epoxidized to eplerenone as described by Pfizer (vide supra) (Scheme 37) [74].
Scheme 37. Synthesis of eplerenone by Chinese Academy of Sciences [74]. Scheme 37. Synthesis of eplerenone by Chinese Academy of Sciences [74].

Drospirenone
Drospirenone (Figure 14) is another steroid spirocyclic lactone drug structurally related to spironolactone and eplerenone, antagonists of mineralocorticoid receptors. However, pharmacologically, drospirenone is different from the latter two drugs. In addition to having a high affinity to mineralocorticoid receptors, it binds rather tightly to progesterone receptors and less tightly to androgen receptors [75], which underlies its use as a birth control medication approved in 2000 [76]. Figure 14) is another steroid spirocyclic lactone related to spironolactone and eplerenone, antagonists of mineraloc However, pharmacologically, drospirenone is different from the la addition to having a high affinity to mineralocorticoid receptors, it bin progesterone receptors and less tightly to androgen receptors [75], whi as a birth control medication approved in 2000 [76]. The earliest synthesis of drospirenone was published by Scherin The synthesis commenced with compound 128, obtained from androstadien-17-one by Corey cyclopropanation. Microbial hydroxy diol 129, which was mono-pivaloylated at the less-hindered hydroxyl g alcohol 130. The olefinic portion of 130 was epoxidized with tert-bu under vanadium(IV) oxide-acetylacetonate catalysis. The resulting converted to chloride 132 by treatment with Ph3P/CCl4 in pyridine. Re of the chlorine atom on treatment with zinc in acetic acid, followed produced the diol 133. The la er was subjected to Simmons-Smith cy establish the basic core of the target compound (134). Now the scene the spirocyclic lactone moiety. Propargylic alcohol was doubly depro to the ketone portion of 134, to give propargylic tetraol 135. The trip hydrogenated over calcium carbonate. The resulting compound 136 PDC, which triggered three events: oxidation of the primary alcohol m acid and lactonization, oxidation of the secondary alcohol to ketone, a form the α,β-unsaturated system of drospirenone (Scheme 38). The earliest synthesis of drospirenone was published by Schering AG in 1982 [77]. The synthesis commenced with compound 128, obtained from 3β-hydroxy-5,15-androstadien-17-one by Corey cyclopropanation. Microbial hydroxylation of 128 gave diol 129, which was mono-pivaloylated at the less-hindered hydroxyl group, to give allylic alcohol 130. The olefinic portion of 130 was epoxidized with tert-butyl hydroperoxide under vanadium(IV) oxide-acetylacetonate catalysis. The resulting epoxide 131 was converted to chloride 132 by treatment with Ph 3 P/CCl 4 in pyridine. Reductive elimination of the chlorine atom on treatment with zinc in acetic acid, followed by saponification, produced the diol 133. The latter was subjected to Simmons-Smith cyclopropanation, to establish the basic core of the target compound (134). Now the scene was set to establish the spirocyclic lactone moiety. Propargylic alcohol was doubly deprotonated and added to the ketone portion of 134, to give propargylic tetraol 135. The triple bond in 135 was hydrogenated over calcium carbonate. The resulting compound 136 was treated with PDC, which triggered three events: oxidation of the primary alcohol moiety to carboxylic acid and lactonization, oxidation of the secondary alcohol to ketone, and dehydration, to form the α,β-unsaturated system of drospirenone (Scheme 38).

Drospirenone (
An approach similar in spirit to the synthesis of drospirenone by Schering AG was patented in 2010 by Evestra, Inc. [78]. The synthesis starts with bis-cyclopropane 134, to which the C-anion of ethyl propiolate was added to the carbonyl group. Hydrogenation of the triple bond in the resulting intermediate 137 gave triol 138, in which the secondary alcohol moiety was oxidized by TEMPO. Treatment of ketone 139 with methanolic potassium hydroxide followed by acidification with acetic acid led to the formation of spirocyclic lactone and the dehydration of the β-hydroxy cyclohexanone moiety, which resulted in drospirenone (Scheme 39).
A different approach to the construction of drospirenone's spirocyclic lactone motif was reported in 2008 by a University of Bologna group [79]. Ketone 134 was treated with excess vinyl magnesium bromide. The resulting tertiary allylic alcohol 140 was involved in the olefin metathesis reaction with methyl acrylate catalyzed by the second-generation Hoveyda-Grubbs catalyst. The resulting intermediate 141, having all the requisite carbon atoms necessary for the formation of spirocyclic γ-lactone, was hydrogenated over palladium on charcoal, which resulted in the reduction of the double bond and the lactone ring closure, to give 142. Final steps toward drospirenone were the Dess-Martin oxidation of the secondary alcohol moiety and the dehydration of the resulting ketone (Scheme 40). An approach similar in spirit to the synthesis of drospirenone by Schering AG was patented in 2010 by Evestra, Inc. [78]. The synthesis starts with bis-cyclopropane 134, to which the C-anion of ethyl propiolate was added to the carbonyl group. Hydrogenation of the triple bond in the resulting intermediate 137 gave triol 138, in which the secondary alcohol moiety was oxidized by TEMPO. Treatment of ketone 139 with methanolic potassium hydroxide followed by acidification with acetic acid led to the formation of spirocyclic lactone and the dehydration of the β-hydroxy cyclohexanone moiety, which resulted in drospirenone (Scheme 39).

Scheme 38.
Synthesis of drospirenone by Schering AG [77]. A different approach to the construction of drospirenone's spirocyclic lactone motif was reported in 2008 by a University of Bologna group [79]. Ketone 134 was treated with excess vinyl magnesium bromide. The resulting tertiary allylic alcohol 140 was involved in the olefin metathesis reaction with methyl acrylate catalyzed by the second-generation Hoveyda-Grubbs catalyst. The resulting intermediate 141, having all the requisite carbon atoms necessary for the formation of spirocyclic γ-lactone, was hydrogenated over Scheme 39. Evestra, Inc. synthesis of drospirenone [78].

Ledipasvir
Ledipasvir (Figure 15), an inhibitor of the hepatitis C virus non-structural protein 5A (HCV NS5A) was developed by Gilead Sciences and was approved in 2014 for the treatment of genotype 1 HCV in combination with sofosbuvir [80]. The pertinence of this drug to the present review is determined by the spirocyclic pyrrolidine moiety in its structure. The complexity of ledipasvir's structure mandates a lengthy synthetic route to assemble the drug molecule. The original synthesis patented by Gilead in 2013 [81] is presented in Scheme 41. The synthetic scheme includes the assembly of the requisite building blocks from four different directions, thereby being remarkably convergent. From one direction, 2-bromofluorene (143) was iodinated in position 7, to give 144. The methylene group in the la er was bis-fluorinated with N-fluorobenzenesulfonimide (NFSI) to give compound 145, which was converted to an aryl magnesium species at the Scheme 40. University of Bologna synthesis of drospirenone [79].

Ledipasvir
Ledipasvir (Figure 15), an inhibitor of the hepatitis C virus non-structural protein 5A (HCV NS5A) was developed by Gilead Sciences and was approved in 2014 for the treatment of genotype 1 HCV in combination with sofosbuvir [80]. The pertinence of this drug to the present review is determined by the spirocyclic pyrrolidine moiety in its structure.

Ledipasvir
Ledipasvir (Figure 15), an inhibitor of the hepatitis C virus non-structural protein 5A (HCV NS5A) was developed by Gilead Sciences and was approved in 2014 for the treatment of genotype 1 HCV in combination with sofosbuvir [80]. The pertinence of this drug to the present review is determined by the spirocyclic pyrrolidine moiety in its structure. The complexity of ledipasvir's structure mandates a lengthy synthetic route to assemble the drug molecule. The original synthesis patented by Gilead in 2013 [81] is presented in Scheme 41. The synthetic scheme includes the assembly of the requisite building blocks from four different directions, thereby being remarkably convergent. From one direction, 2-bromofluorene (143) was iodinated in position 7, to give 144. The methylene group in the la er was bis-fluorinated with N-fluorobenzenesulfonimide (NFSI) to give compound 145, which was converted to an aryl magnesium species at the The complexity of ledipasvir's structure mandates a lengthy synthetic route to assemble the drug molecule. The original synthesis patented by Gilead in 2013 [81] is presented in Scheme 41. The synthetic scheme includes the assembly of the requisite building blocks from four different directions, thereby being remarkably convergent. From one direction, 2-bromofluorene (143) was iodinated in position 7, to give 144. The methylene group in the latter was bis-fluorinated with N-fluorobenzenesulfonimide (NFSI) to give compound 145, which was converted to an aryl magnesium species at the more reactive, iodo side and coupled with chloroacetic acid Weireb amide to give building block 146. From another direction, Boc-protected 4-methylene L-proline (147) was converted to spiro dibromo cyclopropane 148, which was dibrominated and converted to potassium carboxylate 149.
The latter was involved in a nucleophilic substitution reaction with the chloroacetyl compound 146 to give keto ester 150, which was reacted with ammonium acetate to give the imidazole 151. The assembly of the bicyclic pyrrolidine portion of ledipasvir started with enantiopure α-methyl benzylamine (152,) which was used to form a Schiff base with methyl glyoxylate hemiacetal. The Schiff base was involved in a Lewis acid-catalyzed Diels-Alder reaction with cyclopentadiene, and the desired bicyclic structure was established (compound 153). Three trivial transformations (debenzylation with double bond reduction, Boc-protection and ester hydrolysis) gave carboxylic acid 154, which was employed in benzimidazole synthesis to give compound 155. Now the two halves of the ledipasvir molecule (151 and 155) were brought together via a Suzuki coupling involving the in situ formation of the aryl boronic acid intermediate. The resulting intermediate 156 was deprotected and acylated at both liberated nitrogen atoms with N-methoxycarbonyl valine, to give lidepasvir.
Molecules 2023, 28, 4209 32 of 51 more reactive, iodo side and coupled with chloroacetic acid Weireb amide to give building block 146. From another direction, Boc-protected 4-methylene L-proline (147) was converted to spiro dibromo cyclopropane 148, which was dibrominated and converted to potassium carboxylate 149. The la er was involved in a nucleophilic substitution reaction with the chloroacetyl compound 146 to give keto ester 150, which was reacted with ammonium acetate to give the imidazole 151. The assembly of the bicyclic pyrrolidine portion of ledipasvir started with enantiopure α-methyl benzylamine (152,) which was used to form a Schiff base with methyl glyoxylate hemiacetal. The Schiff base was involved in a Lewis acid-catalyzed Diels-Alder reaction with cyclopentadiene, and the desired bicyclic structure was established (compound 153). Three trivial transformations (debenzylation with double bond reduction, Boc-protection and ester hydrolysis) gave carboxylic acid 154, which was employed in benzimidazole synthesis to give compound Scheme 41. Gilead Sciences' synthesis of ledipasvir [81].
The Gilead Sciences route to ledipasvir may well be quite optimal, considering that there have not been any a empts to improve it as judged by the literature on the subject. However, in 2021, a Suzuki-Miyaura coupling of the two halves of the ledipasvir molecule was selected as a drug synthesis example to illustrate the power of the novel aryl halide to aryl boronic acid coupling protocol where no palladium catalyst is employed. The two research groups from China reported the use of the organocatalyst 157 to bring about the coupling of the aryl bromide 151 with the boronic acid pinacol ester 158. Considering the high yield of the advanced ledipasvir precursor 156 reported for this coupling, this Scheme 41. Gilead Sciences' synthesis of ledipasvir [81].
The Gilead Sciences route to ledipasvir may well be quite optimal, considering that there have not been any attempts to improve it as judged by the literature on the subject. However, in 2021, a Suzuki-Miyaura coupling of the two halves of the ledipasvir molecule was selected as a drug synthesis example to illustrate the power of the novel aryl halide to aryl boronic acid coupling protocol where no palladium catalyst is employed. The two research groups from China reported the use of the organocatalyst 157 to bring about the coupling of the aryl bromide 151 with the boronic acid pinacol ester 158. Considering the high yield of the advanced ledipasvir precursor 156 reported for this coupling, this palladium-free approach appears much more amenable to large-scale pharmaceutical production than the original Gilead Sciences route (Scheme 42) [82].

Rolapitant
Rolapitant (Figure 16), a spirocyclic neurokinin NK1 receptor antagonist comprising three stereogenic centers originated in the laboratories of Schering-Plough, and was approved for the treatment of chemotherapy-induced nausea and vomiting in 2015 [83]. The drug's syntheses are primarily featured in the patent literature. The original synthesis of rolapitant patented by Schering-Plough [84] relies on the supply of the key building block 159. Synthetically, the la er can be traced back to (S)phenylglycine over eight synthetic operations, including the preparation of oxazolidinone 160, as detailed further below. Cyclic enamine 159 was subjected to standard hydroboration-oxidation conditions, to afford alcohol 161, which was oxidized to ketone 162 under the Swern conditions. Ketone 162 was involved in a standard hydantoin synthesis with potassium cyanide and ammonium carbonate, to afford spirocyclic compound 163. The la er was Boc-protected, hydrolyzed and Boc-protected again to give α-amino acid 164. The carboxylic group in 164 was reduced via a mixed anhydride to give amino alcohol 165 which was oxidized (again under the Swern conditions) and involved, without protection of the amino group, in a Horner-Wadsworth-Emmons olefination, to give the acrylate ester 166. The la er turned out to be a direct precursor of rolapitant, and was converted to the drug by hydrogenation (accompanied by lactam formation) and protecting group removal (Scheme 43).
As to the synthesis of key building block 159 from (S)-phenylglycine ((S)-Phg), it was accomplished as follows. (S)-Phg was converted to diastereomerically pure oxazolidinone 160 on condensation with benzaldehyde and Cbz-protection [85]. Oxazolidinone 160 was C-alkylated in diastereoselective fashion with chiral bromide 167. The carbonyl group of the resulting intermediate 168 was reduced by lithium alumohydride, and the lactol 169 was obtained. The aldehyde form of the la er reacted with phosphonium ylide generated from the alkyl phosphonium bromide 170, and the elaborate olefinic building block 171 was obtained. It was hydrogenated over platinum dioxide and the resulting acetal 172 was treated with p-toluene sulfonic acid in refluxing ethanol. This led to the removal of the Scheme 42. Palladium-free Suzuki-Miyaura-type coupling towards ledipasvir.

Rolapitant
Rolapitant (Figure 16), a spirocyclic neurokinin NK1 receptor antagonist comprising three stereogenic centers originated in the laboratories of Schering-Plough, and was approved for the treatment of chemotherapy-induced nausea and vomiting in 2015 [83]. The drug's syntheses are primarily featured in the patent literature.

Rolapitant
Rolapitant (Figure 16), a spirocyclic neurokinin NK1 receptor antagonist comprising three stereogenic centers originated in the laboratories of Schering-Plough, and was approved for the treatment of chemotherapy-induced nausea and vomiting in 2015 [83]. The drug's syntheses are primarily featured in the patent literature. The original synthesis of rolapitant patented by Schering-Plough [84] relies on the supply of the key building block 159. Synthetically, the la er can be traced back to (S)phenylglycine over eight synthetic operations, including the preparation of oxazolidinone 160, as detailed further below. Cyclic enamine 159 was subjected to standard hydroboration-oxidation conditions, to afford alcohol 161, which was oxidized to ketone 162 under the Swern conditions. Ketone 162 was involved in a standard hydantoin synthesis with potassium cyanide and ammonium carbonate, to afford spirocyclic compound 163. The la er was Boc-protected, hydrolyzed and Boc-protected again to give α-amino acid 164. The carboxylic group in 164 was reduced via a mixed anhydride to give amino alcohol 165 which was oxidized (again under the Swern conditions) and involved, without protection of the amino group, in a Horner-Wadsworth-Emmons olefination, to give the acrylate ester 166. The la er turned out to be a direct precursor of rolapitant, and was converted to the drug by hydrogenation (accompanied by lactam formation) and protecting group removal (Scheme 43).
As to the synthesis of key building block 159 from (S)-phenylglycine ((S)-Phg), it was accomplished as follows. (S)-Phg was converted to diastereomerically pure oxazolidinone 160 on condensation with benzaldehyde and Cbz-protection [85]. Oxazolidinone 160 was C-alkylated in diastereoselective fashion with chiral bromide 167. The carbonyl group of the resulting intermediate 168 was reduced by lithium alumohydride, and the lactol 169 was obtained. The aldehyde form of the la er reacted with phosphonium ylide generated from the alkyl phosphonium bromide 170, and the elaborate olefinic building block 171 was obtained. It was hydrogenated over platinum dioxide and the resulting acetal 172 was treated with p-toluene sulfonic acid in refluxing ethanol. This led to the removal of the The original synthesis of rolapitant patented by Schering-Plough [84] relies on the supply of the key building block 159. Synthetically, the latter can be traced back to (S)-phenylglycine over eight synthetic operations, including the preparation of oxazolidinone 160, as detailed further below. Cyclic enamine 159 was subjected to standard hydroboration-oxidation conditions, to afford alcohol 161, which was oxidized to ketone 162 under the Swern conditions. Ketone 162 was involved in a standard hydantoin synthesis with potassium cyanide and ammonium carbonate, to afford spirocyclic compound 163. The latter was Boc-protected, hydrolyzed and Boc-protected again to give α-amino acid 164. The carboxylic group in 164 was reduced via a mixed anhydride to give amino alcohol 165 which was oxidized (again under the Swern conditions) and involved, without protection of the amino group, in a Horner-Wadsworth-Emmons olefination, to give the acrylate ester 166. The latter turned out to be a direct precursor of rolapitant, and was converted to the drug by hydrogenation (accompanied by lactam formation) and protecting group removal (Scheme 43).
As to the synthesis of key building block 159 from (S)-phenylglycine ((S)-Phg), it was accomplished as follows. (S)-Phg was converted to diastereomerically pure oxazolidinone 160 on condensation with benzaldehyde and Cbz-protection [85]. Oxazolidinone 160 was C-alkylated in diastereoselective fashion with chiral bromide 167. The carbonyl group of the resulting intermediate 168 was reduced by lithium alumohydride, and the lactol 169 was obtained. The aldehyde form of the latter reacted with phosphonium ylide generated from the alkyl phosphonium bromide 170, and the elaborate olefinic building block 171 was obtained. It was hydrogenated over platinum dioxide and the resulting acetal 172 was treated with p-toluene sulfonic acid in refluxing ethanol. This led to the removal of the acetal protecting group and the cyclization of the Cbz-protected amino group onto the liberated aldehyde carbonyl group, to give the target key intermediate 159 (Scheme 44) [84]. In 2013, Opko Health, Inc. patented an alternative route to rolapitant which is also based on the key building block 159 [86]. This intermediate was nitrated and reduced by lithium borohydride to give the nitro alkane 173. Removal of the Cbz group (to give 174) and subsequent alkylation of the nitro alkane portion with methyl acrylate over basic alumina gave compound 175, which was converted to the methanesulfonic acid salt 176, for easy isolation. The reduction of 176 with zinc metal in acetic acid triggered lactamization and gave rolapitant (Scheme 45). Thus, the Opko Health, Inc. synthesis appears to be shorter than the original Schering-Plough route and more amenable to large scale API production. In 2016, Opko Health, Inc. patented a fundamentally different route to rolapitant which relied on the chiral building block 177 (for the sake of brevity, we do not discuss its synthesis) [87]. It was reductively alkylated with the masked aldehyde building block 178 to give the bis-olefinic compound 179. In the la er, a scene was set for intramolecular olefin metathesis, which was successfully brought about using the Hoveyda-Grubbs second-generation ruthenium catalysts (HGII), and the resulting spirocycle 180 was isolated as hydrochloride salt. The la er advanced intermediate was free-based by aqueous sodium hydroxide and hydrogenated over palladium on charcoal, to give rolapitant (Scheme 46). In 2016, Opko Health, Inc. patented a fundamentally different route to rolapitant which relied on the chiral building block 177 (for the sake of brevity, we do not discuss its synthesis) [87]. It was reductively alkylated with the masked aldehyde building block 178 to give the bis-olefinic compound 179. In the latter, a scene was set for intramolecular olefin metathesis, which was successfully brought about using the Hoveyda-Grubbs secondgeneration ruthenium catalysts (HGII), and the resulting spirocycle 180 was isolated as hydrochloride salt. The latter advanced intermediate was free-based by aqueous sodium hydroxide and hydrogenated over palladium on charcoal, to give rolapitant (Scheme 46). In 2016, Opko Health, Inc. patented a fundamentally different route to rolapitant which relied on the chiral building block 177 (for the sake of brevity, we do not discuss its synthesis) [87]. It was reductively alkylated with the masked aldehyde building block 178 to give the bis-olefinic compound 179. In the la er, a scene was set for intramolecular olefin metathesis, which was successfully brought about using the Hoveyda-Grubbs second-generation ruthenium catalysts (HGII), and the resulting spirocycle 180 was isolated as hydrochloride salt. The la er advanced intermediate was free-based by aqueous sodium hydroxide and hydrogenated over palladium on charcoal, to give rolapitant (Scheme 46).

Apalutamide
Apalutamide (Figure 17), a spirocyclic androgen receptor antagonist discovered by the Sawyers/Jung team at UCLA was approved for the treatment of prostate cancer in the US in 2018 and in Europe in 2019 [88]. The original synthesis was patented in 2007 by the discovery team [89]. It started with the benzoyl chloride 181, which was reacted with methylamine and the resulting amide 182 was involved in an aromatic nucleophilic substitution reaction with p-methoxybenzylamine, to give 183. Upon removal of the PMB group, aniline 184 was involved in a Strecker reaction with cyclobutanone, to give nitrile 185. The monothiohydantoin ring of apalutamide was formed on microwavepromoted condensation with the thioisocyanate 186, followed by acidic hydrolysis on the initially formed imine (Scheme 47).

Apalutamide
Apalutamide (Figure 17), a spirocyclic androgen receptor antagonist discovered by the Sawyers/Jung team at UCLA was approved for the treatment of prostate cancer in the US in 2018 and in Europe in 2019 [88]. The original synthesis was patented in 2007 by the discovery team [89]. It started with the benzoyl chloride 181, which was reacted with methylamine and the resulting amide 182 was involved in an aromatic nucleophilic substitution reaction with p-methoxybenzylamine, to give 183. Upon removal of the PMB group, aniline 184 was involved in a Strecker reaction with cyclobutanone, to give nitrile 185. The monothiohydantoin ring of apalutamide was formed on microwave-promoted condensation with the thioisocyanate 186, followed by acidic hydrolysis on the initially formed imine (Scheme 47).

Apalutamide
Apalutamide (Figure 17), a spirocyclic androgen receptor antagonist discovered by the Sawyers/Jung team at UCLA was approved for the treatment of prostate cancer in the US in 2018 and in Europe in 2019 [88]. The original synthesis was patented in 2007 by the discovery team [89]. It started with the benzoyl chloride 181, which was reacted with methylamine and the resulting amide 182 was involved in an aromatic nucleophilic substitution reaction with p-methoxybenzylamine, to give 183. Upon removal of the PMB group, aniline 184 was involved in a Strecker reaction with cyclobutanone, to give nitrile 185. The monothiohydantoin ring of apalutamide was formed on microwave-promoted condensation with the thioisocyanate 186, followed by acidic hydrolysis on the initially formed imine (Scheme 47).

Apalutamide
Apalutamide (Figure 17), a spirocyclic androgen receptor antagonist discovered by the Sawyers/Jung team at UCLA was approved for the treatment of prostate cancer in the US in 2018 and in Europe in 2019 [88]. The original synthesis was patented in 2007 by the discovery team [89]. It started with the benzoyl chloride 181, which was reacted with methylamine and the resulting amide 182 was involved in an aromatic nucleophilic substitution reaction with p-methoxybenzylamine, to give 183. Upon removal of the PMB group, aniline 184 was involved in a Strecker reaction with cyclobutanone, to give nitrile 185. The monothiohydantoin ring of apalutamide was formed on microwave-promoted condensation with the thioisocyanate 186, followed by acidic hydrolysis on the initially formed imine (Scheme 47). A number of different approaches to apalutamide, mostly focused on the synthesis of pyridine-3-amine 187 were disclosed [88]. A somewhat different approach to apalutamide assembly which involves two copper(I)-catalysed N-arylation steps was patented in 2018 by Hangzhou Cheminspire Technologies Co., Ltd. (Hangzhou, China) [91]. The synthesis avoided the use of thiophosgene or thiophosgene equivalents by generating the thiohydantoin using potassium thiocyanate. Cyclobutane α-amino acid 188 was used as a partner in the copper(I)-catalyzed reaction with aryl bromide 189, to give carboxylic acid 190. Following esterification, compound 191 was reacted with potassium thiocyanate to give the thiohydantoin portion of apalutamide (192). from which the target drug molecule was crafted via copper(I)-catalyzed arylation with 3-bromopyridine 193 (Scheme 49).
A number of different approaches to apalutamide, mostly focused on the synthesis of pyridine-3-amine 187 were disclosed [88]. A somewhat different approach to apalutamide assembly which involves two copper(I)-catalysed N-arylation steps was patented in 2018 by Hangzhou Cheminspire Technologies Co., Ltd. (Hangzhou, China) [91]. The synthesis avoided the use of thiophosgene or thiophosgene equivalents by generating the thiohydantoin using potassium thiocyanate. Cyclobutane α-amino acid 188 was used as a partner in the copper(I)-catalyzed reaction with aryl bromide 189, to give carboxylic acid 190. Following esterification, compound 191 was reacted with potassium thiocyanate to give the thiohydantoin portion of apalutamide (192). from which the target drug molecule was crafted via copper(I)-catalyzed arylation with 3-bromopyridine 193 (Scheme 49

Moxidectin
Moxidectin (Figure 18), a macrolide antiparasitic drug containing an (S)-1,7dioxaspiro [5.5]undecane motif was derived from Streptomyces bacteria discovered in the late 1980s in an Australian soil sample [92]. It was initially employed for the treatment of helminths in house animals. However, in 2018, moxidectin received FDA approval to treat onchocerciasis (river blindness) in patients aged 12 and older [93]. Moxidectin exerts its antiparasitic action by selectively binding to the parasite's GABA-A and glutamate-gated chloride ion channels [94].

Moxidectin
Moxidectin (Figure 18), a macrolide antiparasitic drug containing an (S)-1,7-dioxaspiro undecane motif was derived from Streptomyces bacteria discovered in the late 1980s in an Australian soil sample [92]. It was initially employed for the treatment of helminths in house animals. However, in 2018, moxidectin received FDA approval to treat onchocerciasis (river blindness) in patients aged 12 and older [93]. Moxidectin exerts its antiparasitic action by selectively binding to the parasite's GABA-A and glutamate-gated chloride ion channels [94].
A number of different approaches to apalutamide, mostly focused on the synthesis of pyridine-3-amine 187 were disclosed [88]. A somewhat different approach to apalutamide assembly which involves two copper(I)-catalysed N-arylation steps was patented in 2018 by Hangzhou Cheminspire Technologies Co., Ltd. (Hangzhou, China) [91]. The synthesis avoided the use of thiophosgene or thiophosgene equivalents by generating the thiohydantoin using potassium thiocyanate. Cyclobutane α-amino acid 188 was used as a partner in the copper(I)-catalyzed reaction with aryl bromide 189, to give carboxylic acid 190. Following esterification, compound 191 was reacted with potassium thiocyanate to give the thiohydantoin portion of apalutamide (192

Moxidectin
Moxidectin (Figure 18), a macrolide antiparasitic drug containing an (S)-1,7dioxaspiro [5.5]undecane motif was derived from Streptomyces bacteria discovered in the late 1980s in an Australian soil sample [92]. It was initially employed for the treatment of helminths in house animals. However, in 2018, moxidectin received FDA approval to treat onchocerciasis (river blindness) in patients aged 12 and older [93]. Moxidectin exerts its antiparasitic action by selectively binding to the parasite's GABA-A and glutamate-gated chloride ion channels [94].  Chemically, moxidectin belongs to the milbemycin class of macrocyclic lactones. It is obtained by the semisynthetic modification of nemadectin (F-29249α) which, in turn, is isolated from the fermentation broth of the bacterium Streptomyces cyanogriseus [95]. The following four-step synthesis of moxidectin from nemadectin was disclosed in a 1991 patent [96]. The secondary alcohol hydroxy group on the hexahydrobenzofuran moiety was chemoselectively protected by a p-nitrobenzoate (PNB) ester (194). Then the other secondary alcohol hydroxy group was subjected to Albright-Goldman oxidation (DMSO/acetic anhydride), to give ketone 195, which was converted to O-methyl oxime 196, and the PNB group was removed by alkaline hydrolysis (without any damage to the macrolide ester linkage) to give moxidectin (Scheme 50).
Molecules 2023, 28, 4209 39 of Chemically, moxidectin belongs to the milbemycin class of macrocyclic lactones. It obtained by the semisynthetic modification of nemadectin (F-29249α) which, in turn, isolated from the fermentation broth of the bacterium Streptomyces cyanogriseus [95]. T following four-step synthesis of moxidectin from nemadectin was disclosed in a 19 patent [96]. The secondary alcohol hydroxy group on the hexahydrobenzofuran moie was chemoselectively protected by a p-nitrobenzoate (PNB) ester (194). Then the oth secondary alcohol hydroxy group was subjected to Albright-Goldman oxidati (DMSO/acetic anhydride), to give ketone 195, which was converted to O-methyl oxim 196, and the PNB group was removed by alkaline hydrolysis (without any damage to t macrolide ester linkage) to give moxidectin (Scheme 50).

Ubrogepant
Migraine is a debilitating disease which was traditionally treated on symptomatically by serotonin receptor modulators or non-steroidal anti-inflammato drugs. However, more recent in-depth investigation of the mechanisms underlying t onset of migraine established the calcitonin gene related peptide (CGRP) as a prima player in this pathological process. Produced in peripheral and central neurons, CGRP a potent vasodilator and mediator of nociception. Thus, antagonizing the binding CGRP to its receptor was established as a novel approach to the treatment of acu migraine at the fundamental level [97]. Ubrogepant ( Figure 19) is the first-in-class dr developed by Merck and Co., and was approved in 2020 [98].

Ubrogepant
Migraine is a debilitating disease which was traditionally treated only symptomatically by serotonin receptor modulators or non-steroidal anti-inflammatory drugs. However, more recent in-depth investigation of the mechanisms underlying the onset of migraine established the calcitonin gene related peptide (CGRP) as a primary player in this pathological process. Produced in peripheral and central neurons, CGRP is a potent vasodilator and mediator of nociception. Thus, antagonizing the binding of CGRP to its receptor was established as a novel approach to the treatment of acute migraine at the fundamental level [97]. Ubrogepant ( Figure 19) is the first-in-class drug developed by Merck and Co., and was approved in 2020 [98].
Chemically, moxidectin belongs to the milbemycin class of macrocyclic lactones. It is obtained by the semisynthetic modification of nemadectin (F-29249α) which, in turn, is isolated from the fermentation broth of the bacterium Streptomyces cyanogriseus [95]. The following four-step synthesis of moxidectin from nemadectin was disclosed in a 1991 patent [96]. The secondary alcohol hydroxy group on the hexahydrobenzofuran moiety was chemoselectively protected by a p-nitrobenzoate (PNB) ester (194). Then the other secondary alcohol hydroxy group was subjected to Albright-Goldman oxidation (DMSO/acetic anhydride), to give ketone 195, which was converted to O-methyl oxime 196, and the PNB group was removed by alkaline hydrolysis (without any damage to the macrolide ester linkage) to give moxidectin (Scheme 50).

Ubrogepant
Migraine is a debilitating disease which was traditionally treated only symptomatically by serotonin receptor modulators or non-steroidal anti-inflammatory drugs. However, more recent in-depth investigation of the mechanisms underlying the onset of migraine established the calcitonin gene related peptide (CGRP) as a primary player in this pathological process. Produced in peripheral and central neurons, CGRP is a potent vasodilator and mediator of nociception. Thus, antagonizing the binding of CGRP to its receptor was established as a novel approach to the treatment of acute migraine at the fundamental level [97]. Ubrogepant ( Figure 19) is the first-in-class drug developed by Merck and Co., and was approved in 2020 [98]. The detailed process of the chemical route towards ubrogepant was published by the Merck team in 2017 [99]. The final step in the assembly of the target molecule was the amidation of the enantiopure spirocyclic carboxylic acid 197 with the enantiopure amine 198 hydrochloride salt (Scheme 51).
Scheme 51. Final amidation in the assembly of ubrogepant. Therefore, it is the assembly of enantiopure building blocks 197 and 198 which required most of the innovation. The synthesis of amine 198 started with a diastereomeric mixture of keto esters 199. The la er was subjected to dynamic kinetic transaminasemediated cyclization (using an evolved enzyme strain) to give piperidone 200 as a 3:2 mixture of epimers. N-Alkylation of the la er with 3,3,3-trifluoroethyl triflate afforded predominantly compound 201 (separated in 87% yield from the unreacted starting material and bis-alkylation product). Removal of the Boc group gave the epimeric amine 202, which was subjected to crystallization-induced diastereoselective transformation (CIDT) with p-toluic acid and 3,5-dichlorosalicylic aldehyde to give building block 203, which was converted to the hydrochloride salt 198 (Scheme 52). The spirocyclic carboxylic acid 197 was assembled as follows. The 2,3-Dibromo-5chloropyridine (204) was transformed in four steps (involving two additions of pyridine magnesium species to DMF) to hte tetrahydropyran-protected aldehyde 205. The la er was condensed with 7-azaindolin-2-one 206 to give the olefin 207, which was reduced by sodium borohydride, and the THP group was removed to give the alcohol 208. Therefore, it is the assembly of enantiopure building blocks 197 and 198 which required most of the innovation. The synthesis of amine 198 started with a diastereomeric mixture of keto esters 199. The latter was subjected to dynamic kinetic transaminase-mediated cyclization (using an evolved enzyme strain) to give piperidone 200 as a 3:2 mixture of epimers. N-Alkylation of the latter with 3,3,3-trifluoroethyl triflate afforded predominantly compound 201 (separated in 87% yield from the unreacted starting material and bisalkylation product). Removal of the Boc group gave the epimeric amine 202, which was subjected to crystallization-induced diastereoselective transformation (CIDT) with p-toluic acid and 3,5-dichlorosalicylic aldehyde to give building block 203, which was converted to the hydrochloride salt 198 (Scheme 52). The detailed process of the chemical route towards ubrogepant was published by the Merck team in 2017 [99]. The final step in the assembly of the target molecule was the amidation of the enantiopure spirocyclic carboxylic acid 197 with the enantiopure amine 198 hydrochloride salt (Scheme 51).
Scheme 51. Final amidation in the assembly of ubrogepant.
Therefore, it is the assembly of enantiopure building blocks 197 and 198 which required most of the innovation. The synthesis of amine 198 started with a diastereomeric mixture of keto esters 199. The la er was subjected to dynamic kinetic transaminasemediated cyclization (using an evolved enzyme strain) to give piperidone 200 as a 3:2 mixture of epimers. N-Alkylation of the la er with 3,3,3-trifluoroethyl triflate afforded predominantly compound 201 (separated in 87% yield from the unreacted starting material and bis-alkylation product). Removal of the Boc group gave the epimeric amine 202, which was subjected to crystallization-induced diastereoselective transformation (CIDT) with p-toluic acid and 3,5-dichlorosalicylic aldehyde to give building block 203, which was converted to the hydrochloride salt 198 (Scheme 52). The spirocyclic carboxylic acid 197 was assembled as follows. The 2,3-Dibromo-5chloropyridine (204) was transformed in four steps (involving two additions of pyridine magnesium species to DMF) to hte tetrahydropyran-protected aldehyde 205. The la er was condensed with 7-azaindolin-2-one 206 to give the olefin 207, which was reduced by sodium borohydride, and the THP group was removed to give the alcohol 208. The spirocyclic carboxylic acid 197 was assembled as follows. The 2,3-Dibromo-5chloropyridine (204) was transformed in four steps (involving two additions of pyridine magnesium species to DMF) to hte tetrahydropyran-protected aldehyde 205. The latter was condensed with 7-azaindolin-2-one 206 to give the olefin 207, which was reduced by sodium borohydride, and the THP group was removed to give the alcohol 208. Conversion of 208 into the alkyl chloride 209 set the scene for spirocyclization. On the action of aqueous sodium hydroxide, in the presence of the cinchona alkaloid-derived chiral catalyst 210, chloride 209 underwent an efficient and enantioselective intramolecular C-alkylation to form the spirocycle 211. Palladium-catalyzed carbonylation of the chloropyridine portion in the latter, followed by the removal of the tert-butyl group from the lactam nitrogen atom, afforded the key spirocyclic carboxylic acid 197 (Scheme 53). of the chloropyridine portion in the la er, followed by the removal of the tert-butyl group from the lactam nitrogen atom, afforded the key spirocyclic carboxylic acid 197 (Scheme 53).
An alternative approach to spirocyclic carboxylic acid 197 was reported in 2022 by Hu and co-workers [100]. It involves the direct asymmetric spiroannulation of Bocprotected 7-azaindolin-2-one (213) with the doubly benzylic bis-bromide 212. Thus, from cheap and readily available starting materials, spirocycle 214 was obtained in good yield and enantioselectivity. Removal of the Boc group followed by nitrile hydrolysis gave the requisite spiro acid 197, thus completing a formal synthesis of ubrogepant (Scheme 54).

Oliceridine
Oliceridine (Figure 20), a spirocyclic biased [101] agonist of µ-opioid receptors was developed by Trevena, Inc. and was approved in 2020 for the intravenous treatment of acute moderate-to-severe post-operative pain [102]. An alternative approach to spirocyclic carboxylic acid 197 was reported in 2022 by Hu and co-workers [100]. It involves the direct asymmetric spiroannulation of Boc-protected 7-azaindolin-2-one (213) with the doubly benzylic bis-bromide 212. Thus, from cheap and readily available starting materials, spirocycle 214 was obtained in good yield and enantioselectivity. Removal of the Boc group followed by nitrile hydrolysis gave the requisite spiro acid 197, thus completing a formal synthesis of ubrogepant (Scheme 54).
Molecules 2023, 28, 4209 41 of 51 of the chloropyridine portion in the la er, followed by the removal of the tert-butyl group from the lactam nitrogen atom, afforded the key spirocyclic carboxylic acid 197 (Scheme 53).
An alternative approach to spirocyclic carboxylic acid 197 was reported in 2022 by Hu and co-workers [100]. It involves the direct asymmetric spiroannulation of Bocprotected 7-azaindolin-2-one (213) with the doubly benzylic bis-bromide 212. Thus, from cheap and readily available starting materials, spirocycle 214 was obtained in good yield and enantioselectivity. Removal of the Boc group followed by nitrile hydrolysis gave the requisite spiro acid 197, thus completing a formal synthesis of ubrogepant (Scheme 54).

Oliceridine
Oliceridine (Figure 20), a spirocyclic biased [101] agonist of µ-opioid receptors was developed by Trevena, Inc. and was approved in 2020 for the intravenous treatment of acute moderate-to-severe post-operative pain [102].

Oliceridine
Oliceridine (Figure 20), a spirocyclic biased [101] agonist of µ-opioid receptors was developed by Trevena, Inc. and was approved in 2020 for the intravenous treatment of acute moderate-to-severe post-operative pain [102].
of the chloropyridine portion in the la er, followed by the removal of the tert-butyl group from the lactam nitrogen atom, afforded the key spirocyclic carboxylic acid 197 (Scheme 53).
An alternative approach to spirocyclic carboxylic acid 197 was reported in 2022 by Hu and co-workers [100]. It involves the direct asymmetric spiroannulation of Bocprotected 7-azaindolin-2-one (213) with the doubly benzylic bis-bromide 212. Thus, from cheap and readily available starting materials, spirocycle 214 was obtained in good yield and enantioselectivity. Removal of the Boc group followed by nitrile hydrolysis gave the requisite spiro acid 197, thus completing a formal synthesis of ubrogepant (Scheme 54).

Oliceridine
Oliceridine (Figure 20), a spirocyclic biased [101] agonist of µ-opioid receptors was developed by Trevena, Inc. and was approved in 2020 for the intravenous treatment of acute moderate-to-severe post-operative pain [102].  The only full detailed route to the oliceridine drug substance is the original Trevena, Inc. approach, patented in 2012 [103]. The source of the spirocyclic motif was the ketone 216, obtained by the oxidation of the perhydropyran-4-ol 215, synthesized, in turn, by the Prins cyclization between cyclopentanone and homoallylic alcohol [104]. Base-promoted condensation with methyl cyanoacetate afforded the olefin 217, to which pyrid-2-yl organometallic reagent (magnesium or lithium) was added in conjugate fashion, to give the cyano ester 218. The latter was subjected to basic hydrolysis and decarboxylation at elevated temperature to afford the racemic product, which was resolved by preparative chiral supercritical fluid chromatography to give the enantiopure nitrile 219. This product was reduced using LAH and the resulting amine 220 was reductively alkylated with 3-methoxythiophene-2carboxaldehyde to give oliceridine (Scheme 55).
The only full detailed route to the oliceridine drug substance is the original Trevena, Inc. approach, patented in 2012 [103]. The source of the spirocyclic motif was the ketone 216, obtained by the oxidation of the perhydropyran-4-ol 215, synthesized, in turn, by the Prins cyclization between cyclopentanone and homoallylic alcohol [104]. Base-promoted condensation with methyl cyanoacetate afforded the olefin 217, to which pyrid-2-yl organometallic reagent (magnesium or lithium) was added in conjugate fashion, to give the cyano ester 218. The la er was subjected to basic hydrolysis and decarboxylation at elevated temperature to afford the racemic product, which was resolved by preparative chiral supercritical fluid chromatography to give the enantiopure nitrile 219. This product was reduced using LAH and the resulting amine 220 was reductively alkylated with 3methoxythiophene-2-carboxaldehyde to give oliceridine (Scheme 55).

Risdiplam
Risdiplam (Figure 21) is the first oral medication to treat spinal muscular atrophy, an orphan disease [105]. The drug was developed by PTC Therapeutics and the Spinal Muscular Atrophy Foundation, and received FDA approval in 2020 for the treatment of the disease in patients aged 2 months or older [106]. The drug acts by modifying mRNA splicing by binding to the survival of motor neuron 2 (SMN2) [107]. It is currently marketed by Genentech, a subsidiary of Roche. The synthetic routes to risdiplam disclosed in the original chemical process patents by Roche rely on the commercial supply of the spirocylic piperazine building block, and thus do not involve the formation of the spirocyclic moiety in the course of the synthesis.
In their 2015 patented route, PTC Therapeutics and Roche scientists started with 3,6dichloro-5-methylpyridazine (221), in which the less accessible chlorine atom was

Risdiplam
Risdiplam (Figure 21) is the first oral medication to treat spinal muscular atrophy, an orphan disease [105]. The drug was developed by PTC Therapeutics and the Spinal Muscular Atrophy Foundation, and received FDA approval in 2020 for the treatment of the disease in patients aged 2 months or older [106]. The drug acts by modifying mRNA splicing by binding to the survival of motor neuron 2 (SMN2) [107]. It is currently marketed by Genentech, a subsidiary of Roche.
The only full detailed route to the oliceridine drug substance is the original Trevena, Inc. approach, patented in 2012 [103]. The source of the spirocyclic motif was the ketone 216, obtained by the oxidation of the perhydropyran-4-ol 215, synthesized, in turn, by the Prins cyclization between cyclopentanone and homoallylic alcohol [104]. Base-promoted condensation with methyl cyanoacetate afforded the olefin 217, to which pyrid-2-yl organometallic reagent (magnesium or lithium) was added in conjugate fashion, to give the cyano ester 218. The la er was subjected to basic hydrolysis and decarboxylation at elevated temperature to afford the racemic product, which was resolved by preparative chiral supercritical fluid chromatography to give the enantiopure nitrile 219. This product was reduced using LAH and the resulting amine 220 was reductively alkylated with 3methoxythiophene-2-carboxaldehyde to give oliceridine (Scheme 55).

Risdiplam
Risdiplam (Figure 21) is the first oral medication to treat spinal muscular atrophy, an orphan disease [105]. The drug was developed by PTC Therapeutics and the Spinal Muscular Atrophy Foundation, and received FDA approval in 2020 for the treatment of the disease in patients aged 2 months or older [106]. The drug acts by modifying mRNA splicing by binding to the survival of motor neuron 2 (SMN2) [107]. It is currently marketed by Genentech, a subsidiary of Roche. The synthetic routes to risdiplam disclosed in the original chemical process patents by Roche rely on the commercial supply of the spirocylic piperazine building block, and thus do not involve the formation of the spirocyclic moiety in the course of the synthesis.
In their 2015 patented route, PTC Therapeutics and Roche scientists started with 3,6dichloro-5-methylpyridazine (221), in which the less accessible chlorine atom was The synthetic routes to risdiplam disclosed in the original chemical process patents by Roche rely on the commercial supply of the spirocylic piperazine building block, and thus do not involve the formation of the spirocyclic moiety in the course of the synthesis.
In their 2015 patented route, PTC Therapeutics and Roche scientists started with 3,6-dichloro-5-methylpyridazine (221), in which the less accessible chlorine atom was substituted with ammonia and the imidazo ring was formed on condensation with bromoacetone dimethyl ketal (222). The overall yield of the resulting imidazo pyridazine 223 was obtained in relatively low yield (unsurprisingly, considering the unfavorable course of the initial nucleophilic aromatic substitution). Compound 223 was coupled, under palladium(II) catalysis, with bis(pinacolato)diboron, to give boronic acid 224. The latter was coupled again, in Suzuki fashion, with the pyrido pyrimidone building block 225 (obtained, in turn, from 2-amino-5-fluoropyridine on condensation with dimethyl malonate). The Susuki coupling 224 + 225 resulted in the core risdiplam scaffold 226, which was decorated with spirocyclic piperazine 227 under thermal conditions, to give risdiplam (Scheme 56) [108].
Molecules 2023, 28, 4209 43 of 51 substituted with ammonia and the imidazo ring was formed on condensation with bromoacetone dimethyl ketal (222). The overall yield of the resulting imidazo pyridazine 223 was obtained in relatively low yield (unsurprisingly, considering the unfavorable course of the initial nucleophilic aromatic substitution). Compound 223 was coupled, under palladium(II) catalysis, with bis(pinacolato)diboron, to give boronic acid 224. The la er was coupled again, in Suzuki fashion, with the pyrido pyrimidone building block 225 (obtained, in turn, from 2-amino-5-fluoropyridine on condensation with dimethyl malonate). The Susuki coupling 224 + 225 resulted in the core risdiplam scaffold 226, which was decorated with spirocyclic piperazine 227 under thermal conditions, to give risdiplam (Scheme 56) [108].
For the more recent route following their 2019 patent application, Roche scientists started by involving 5-bromo-2-chloropyridine (228) in Buchwald-Hartwig amination with Boc-protected spirocyclic piperazine (229). The unreacted, under Pd(II)-catalyzed conditions, chlorine atom in 230 was displaced by ammonia under Pd(0) catalysis and the amino portion of the resulting intermediate 231 was converted in two steps into tosylate 232. The la er was coupled with boronic acid 224 (prepared as described in the previous Roche patent) in Suzuki fashion, and the Boc group in the resulting coupling product 233 was removed to give risdiplam (Scheme 57) [109].
For the more recent route following their 2019 patent application, Roche scientists started by involving 5-bromo-2-chloropyridine (228) in Buchwald-Hartwig amination with Boc-protected spirocyclic piperazine (229). The unreacted, under Pd(II)-catalyzed conditions, chlorine atom in 230 was displaced by ammonia under Pd(0) catalysis and the amino portion of the resulting intermediate 231 was converted in two steps into tosylate 232. The latter was coupled with boronic acid 224 (prepared as described in the previous Roche patent) in Suzuki fashion, and the Boc group in the resulting coupling product 233 was removed to give risdiplam (Scheme 57) [109].

Atogepant
Atogepant ( Figure 22) is a next-in-class antagonist of the calcitonin gene-related peptide (CGRP) is a direct analog of ubrogepant (the first-in-class CGRP antagonist developed by Merck, vide supra), which is different from ubrogepant since it contains a 2,3,6-trifluorophenyl ring. Discovered by Merck and developed by AbbVie, atogepant was

Atogepant
Atogepant ( Figure 22) is a next-in-class antagonist of the calcitonin gene-related peptide (CGRP) is a direct analog of ubrogepant (the first-in-class CGRP antagonist developed by Merck, vide supra), which is different from ubrogepant since it contains a 2,3,6-trifluorophenyl ring. Discovered by Merck and developed by AbbVie, atogepant was approved in 2021 for the preventive treatment of episodic migraine in adults [110]. Scheme 57. A 2019 synthesis of risdiplam by Roche [109].

Atogepant
Atogepant ( Figure 22) is a next-in-class antagonist of the calcit peptide (CGRP) is a direct analog of ubrogepant (the first-in-class developed by Merck, vide supra), which is different from ubrogepan 2,3,6-trifluorophenyl ring. Discovered by Merck and developed by Abb approved in 2021 for the preventive treatment of episodic migraine in The synthesis of atogepant was described in detail in a 2016 pa Merck [111], and it relies on essentially the same routine as was used of ubrogepant. Specifically, the same enantiopure spiro acid 197 enantiopure 3-aminopyrid-2-one building block was also assembled to the amine half of ubrogepant (202). The synthesis commenced wi acid, which was converted to the respective acyl chloride and then the The la er was treated with methylmagnesium chloride to give the met la er was alkylated at the most acidic, benzylic position with mesyla ester 238. The la er is a direct analog of compound 199 as a precurs exact same routine, involving the use of dynamic kinetic transam The synthesis of atogepant was described in detail in a 2016 patent application by Merck [111], and it relies on essentially the same routine as was used in the preparation of ubrogepant. Specifically, the same enantiopure spiro acid 197 was in use. The enantiopure 3-aminopyrid-2-one building block was also assembled in a fashion similar to the amine half of ubrogepant (202). The synthesis commenced with the phenylacetic acid, which was converted to the respective acyl chloride and then the Weinreb amide 235. The latter was treated with methylmagnesium chloride to give the methyl ketone 236. The latter was alkylated at the most acidic, benzylic position with mesylate 237 to give keto ester 238. The latter is a direct analog of compound 199 as a precursor to 202-and the exact same routine, involving the use of dynamic kinetic transaminase, was used to convert compound 238 to enantiopure 3-aminopyrid-2-one 239. Amidation of the spiro acid 197 with the amine 239 gave atogepant (Scheme 58). Scheme 58. Synthesis of atogepant by Merck [111].

Trilaciclib
Trilaciclib ( Figure 23) spirocyclic inhibitor of cyclin-dependent kinases 4 and 6 (CDK4 and CDK6) was developed by G1 Therapeutics. The drug was indicated for cancer patients receiving certain types of chemotherapy to protect the bone marrow from chemotherapyinduced damage. As trilaciclib was the first-in-class drug developed for this important indication, it received a priority review and a breakthrough therapy designation from the FDA. It was approved for medical use in 2021 [112].

Trilaciclib
Trilaciclib ( Figure 23) spirocyclic inhibitor of and CDK6) was developed by G1 Therapeutics. T receiving certain types of chemotherapy to protec induced damage. As trilaciclib was the first-in-c indication, it received a priority review and a bre FDA. It was approved for medical use in 2021 [11 The drug's originator patented two synthetic an intramolecular N-acylation as the key step in t [113,114]. Of these two approaches, the later one and is therefore the API production route which The synthesis commences with an efficient cyclohexanone with glycine methyl ester and tri nitrile 240. The la er was hydrogenated over reduction of the nitrile to the aminomethyl compo afford the key spirocyclic building block 241. Wi secondary amine 241 was used to displace the template 242. The nucleophilic aromatic substit conditions and afforded the spirocycle 243, whic pyrrolo portion of the target molecule. As this st the piperazinone moiety, the lactam nitrogen of give compound 244. Treatment of the la er with D deprotonation and intramolecular cyclization, an 245 in quantitative yield over the last two steps (i The drug's originator patented two synthetic routes to the compound, both involving an intramolecular N-acylation as the key step in the construction of the spirocyclic moiety [113,114]. Of these two approaches, the later one [114] is described in much greater detail, and is therefore the API production route which we chose to discuss herein. The synthesis commences with an efficient and high-yielding Strecker reaction of cyclohexanone with glycine methyl ester and trimethylsilyl cyanide, to afford the amino nitrile 240. The latter was hydrogenated over platinum(IV) oxide. This caused the reduction of the nitrile to the aminomethyl compound, which underwent lactamization to afford the key spirocyclic building block 241. Without protection, the sterically hindered secondary amine 241 was used to displace the labile chlorine atom in the pyrimidine template 242. The nucleophilic aromatic substitution reaction proceeded under forcing conditions and afforded the spirocycle 243, which was now set for the formation of the pyrrolo portion of the target molecule. As this step would require C-H deprotonation of the piperazinone moiety, the lactam nitrogen of intermediate 243 was Boc-protected to give compound 244. Treatment of the latter with DBU at 0°C in THF triggered the desired deprotonation and intramolecular cyclization, and gave the 3-hydroxypyrrolo compound 245 in quantitative yield over the last two steps (including the preceding Boc-protection). Clearly, the hydroxy group in 245 had to be removed, which was achieved by O-triflation of the compound with the subsequent palladium(0)-catalyzed reductive coupling with triethylsilane. The two steps resulted in 70% combined yield and afforded the spirocyclic pyrrolo pyrimidine 246, which was deprotected with trifluoroacetic acid to give the advanced trilaciclib precursor 247. To complete the synthesis, the methylthio group in 247 was oxidized to the better, leaving methylsulfonyl group with oxone in aqueous acetonitrile, to give 248 in excellent yield. The final nucleophilic aromatic substitution step between the spirocyclic template 248 and the pyridine amine 249 (prepared, in turn via nucleophilic aromatic substitution with 5-halopyridine precursor and N-methylpiperazine) required the use of a strong base (LiHMDS), and gave trilaciclib (Scheme 59).
advanced trilaciclib precursor 247. To complete the synthesis, the methylthio group in 247 was oxidized to the be er, leaving methylsulfonyl group with oxone in aqueous acetonitrile, to give 248 in excellent yield. The final nucleophilic aromatic substitution step between the spirocyclic template 248 and the pyridine amine 249 (prepared, in turn via nucleophilic aromatic substitution with 5-halopyridine precursor and Nmethylpiperazine) required the use of a strong base (LiHMDS), and gave trilaciclib (Scheme 59). Scheme 59. G1 Therapeutics industrial synthesis of trilaciclib [114].

Conclusions and Perspectives
As noted previously, the use of spirocycles in drug discovery and medicinal chemistry has seen an explosive rise [2]. This trend is clearly reflected in the number of drugs containing a spirocyclic motif which received approval for medical use over the years. Indeed, over 50% of such drug molecules have been approved in this century. A range of synthetic methods to form a spirocyclic scaffold have been employed in the production routes towards these drugs, although at times the source of the spirocyclic Scheme 59. G1 Therapeutics industrial synthesis of trilaciclib [114].

Conclusions and Perspectives
As noted previously, the use of spirocycles in drug discovery and medicinal chemistry has seen an explosive rise [2]. This trend is clearly reflected in the number of drugs containing a spirocyclic motif which received approval for medical use over the years. Indeed, over 50% of such drug molecules have been approved in this century. A range of synthetic methods to form a spirocyclic scaffold have been employed in the production routes towards these drugs, although at times the source of the spirocyclic moiety is the naturally occurring, biosynthesized compound or a commercially available spirocyclic building block ( Table 1).
The trend is likely to continue, resulting in new advanced drug candidates and approved drug molecules, which mandates that the arsenal of synthetic methods applicable to spirocycle formation is expanded beyond the most popular key steps such as lactonization and lactamization, cyclocondensation (including ketalization and acetalization) and including intramolecular C-alkylation and acylation. Given the rate of development of synthetic approaches towards the construction of spirocyclic molecules employing various modern techniques (e.g., photochemistry, multicomponent reactions, diazo chemistry, asymmetric catalysis, flow synthesis, etc.) which is reflected in the high annual publication activity, we have no doubt that many of them will find application in the field of both drug design and industrial production in the near future. Table 1. Summary of approved spirocyclic drugs: year of approval and origin of spirocyclic moiety.

Entry
Drug Name Year of Approval Origin of Spirocycle