Recent Advances in Manganese(III)-Assisted Radical Cyclization for the Synthesis of Natural Products: A Comprehensive Review

Natural products play an important part in synthetic chemistry since they have many pharmacological properties and are used as active drug compounds in pharmaceutical chemistry. However, synthesis of these complex molecules is difficult due to the requirement of various synthetic steps, which include highly regio- and stereoselectivity. Therefore, oxidative radical cyclization assisted by manganese(III) acetate serves as an important step in obtaining spiro-, tricyclic, tetracyclic, and polycyclic derivatives of these compounds. Manganese(III)-based reactions offer a single-step regio- and stereoselective cyclizations and α-acetoxidations, reducing the number of synthetic steps. Also, the manganese(III)-mediated oxidative free radical cyclization method has been successfully applied for the synthesis of cyclic structures found in many natural products. This article presents a broad overview of manganese(III)-based radical reactions of natural products as a key step in overall synthesis. The authors have classified natural product synthesis processes assisted by manganese(III) acetate as intermolecular, intramolecular, oxidation, acetoxidation, aromatization, and polymerization reactions, respectively.

In some reactions, copper(II) acetate is also used along with manganese(III), due to the fact that the oxidizing effect of copper(II) on primary and secondary radicals is stronger than that of manganese.The formed Cu(I) is then oxidized to Cu(II) by Mn(III), meaning that using a catalytic amount of Cu(II) is sufficient [10].
The anhydrous form of manganese(III) acetate is a linear coordination polymer with acetic acid molecules bridging between manganese atoms (Scheme 1A) [46,47].It is usually used as a dihydrate, though the anhydrous form is also used in some situations and is slightly more reactive than the dihydrate.Manganese(III) acetate is easily prepared by reacting potassium permanganate and manganese(II) acetate in acetic acid; the addition of acetic anhydride to the reaction produces the anhydrous form [13].Moreover, Pekel et al. disclosed a continuous electrochemical process for obtaining manganese(III) acetate with high purity [48,49].
Molecules 2024, 29, x FOR PEER REVIEW 2 of 42 nese(III) acetate is the visibility of the free radical reaction, since the initial color changes when the reaction is completed.Mostly acetic acid is used in these reactions due to the ease of dissolving manganese(III) acetate at lower temperatures.However, acetonitrile, ethanol, methanol, dioxane and DMSO are also used.In some reactions, copper(II) acetate is also used along with manganese(III), due to the fact that the oxidizing effect of copper(II) on primary and secondary radicals is stronger than that of manganese.The formed Cu(I) is then oxidized to Cu(II) by Mn(III), meaning that using a catalytic amount of Cu(II) is sufficient [10].
The anhydrous form of manganese(III) acetate is a linear coordination polymer with acetic acid molecules bridging between manganese atoms (Scheme 1A) [46,47].It is usually used as a dihydrate, though the anhydrous form is also used in some situations and is slightly more reactive than the dihydrate.Manganese(III) acetate is easily prepared by reacting potassium permanganate and manganese(II) acetate in acetic acid; the addition of acetic anhydride to the reaction produces the anhydrous form [13].Moreover, Pekel et al. disclosed a continuous electrochemical process for obtaining manganese(III) acetate with high purity [48,49].The mechanism of reaction within manganese(III) acetate has been explained in many articles.To elucidate, the reaction begins with the formation of a manganese(III)enolate complex followed by the reduction of Mn(III) to Mn(II), whilst a carbon radical is formed, which is attacked by an unsaturated species to form a radical intermediate.Additional manganese(III) transforms this radical to carbocation in the termination step, followed by the formation of a cyclic structure [16][17][18][19][20][21][22][23][24][25][26][27][28][29].Oxidation occurs twice in these reactions, such that two equivalents of manganese(III) are needed to undergo these free radical cyclization reactions (Scheme 1B).A general review on free radical reactions with manganese(III) acetate was published by Nishino [6], Demir [7], Snider [8], Mondal [9], and Burton [12].Yet, here, we wish to present manganese(III) acetate-initiated free radical reactions that target natural product synthesis.The mechanism of reaction within manganese(III) acetate has been explained in many articles.To elucidate, the reaction begins with the formation of a manganese(III)-enolate complex followed by the reduction of Mn(III) to Mn(II), whilst a carbon radical is formed, which is attacked by an unsaturated species to form a radical intermediate.Additional manganese(III) transforms this radical to carbocation in the termination step, followed by the formation of a cyclic structure [16][17][18][19][20][21][22][23][24][25][26][27][28][29].Oxidation occurs twice in these reactions, such that two equivalents of manganese(III) are needed to undergo these free radical cyclization reactions (Scheme 1B).A general review on free radical reactions with manganese(III) acetate was published by Nishino [6], Demir [7], Snider [8], Mondal [9], and Burton [12].Yet, here, we wish to present manganese(III) acetate-initiated free radical reactions that target natural product synthesis.
Natural product synthesis is a developing area in synthetic organic chemistry due to its integration with medicinal and combinatorial chemistry, as well as traditional organic chemistry disciplines.Free radical chemistry constitutes the key to natural product synthesis in most forms of natural product synthesis.Particularly, manganese(III) acetate is mostly used as a radical initiator in natural product synthesis due to its versatility, ease of handling, and ready availability, alongside its regioselectivity and stereoselectivity.The purpose of this manuscript is to provide an overview of the pivotal role played by the manganese(III) acetate compound in the synthesis of natural products, targeting researchers and academics engaged in the area of study.To our knowledge, there has been no prior publication addressing this specific aspect.It is our anticipation that this manuscript will serve as a valuable and comprehensive resource, offering insights and guidance to researchers actively involved in the synthesis of natural products.
Natural product synthesis is a developing area in synthetic organic chemistry due to its integration with medicinal and combinatorial chemistry, as well as traditional organic chemistry disciplines.Free radical chemistry constitutes the key to natural product synthesis in most forms of natural product synthesis.Particularly, manganese(III) acetate is mostly used as a radical initiator in natural product synthesis due to its versatility, ease of handling, and ready availability, alongside its regioselectivity and stereoselectivity.The purpose of this manuscript is to provide an overview of the pivotal role played by the manganese(III) acetate compound in the synthesis of natural products, targeting researchers and academics engaged in the area of study.To our knowledge, there has been no prior publication addressing this specific aspect.It is our anticipation that this manuscript will serve as a valuable and comprehensive resource, offering insights and guidance to researchers actively involved in the synthesis of natural products.
Parsons and co-workers accomplished the synthesis of (±)-araliopsine ( 14) alkaloid and its analogues in a one-pot reaction with good yields, starting from quinolone derivatives.These derivatives could yield angular and/or linear tricyclic isomers depending on  Snider et al. reported the synthesis of (±)-conocarpan ( 13), a benzofuranoid neolignan.Intermolecular cyclization was employed to obtain an analogue structure of (±)-conocarpan using 2-cyclohexenone (9) and a styrene derivative (10), as illustrated in Scheme 4.Although starting with 4-allyl-2-cyclohexenone could be considered for the synthesis of (±)-conocarpan, complex products were obtained.
Parsons and co-workers accomplished the synthesis of (±)-araliopsine (14) alkaloid and its analogues in a one-pot reaction with good yields, starting from quinolone derivatives.These derivatives could yield angular and/or linear tricyclic isomers depending on Scheme 4. The synthesis of (±)-conocarpan (13).
Parsons and co-workers accomplished the synthesis of (±)-araliopsine ( 14) alkaloid and its analogues in a one-pot reaction with good yields, starting from quinolone derivatives.These derivatives could yield angular and/or linear tricyclic isomers depending on the substituents on the alkene, as illustrated in Scheme 5 [53].Additionally, a subsequent study by Bar et al. investigated the synthesis of similar quinolone derivatives with various substituents, including alkyl, alkynyl, and aryl groups, resulting in yields ranging from poor to good [54].
the substituents on the alkene, as illustrated in Scheme 5 [53].Additionally, a subsequent study by Bar et al. investigated the synthesis of similar quinolone derivatives with various substituents, including alkyl, alkynyl, and aryl groups, resulting in yields ranging from poor to good [54].
Garzino has described an efficient method for the synthesis of (+)-phyltetralin (19) derivatives in four steps, with an overall yield of 19% (Scheme 6).A β-ketoester was utilized as a precursor for the synthesis, and oxidative cyclization by manganese(III) was the key step to achieve the synthesis of the target molecule [55].Scheme 6. (+)-Phyltetralin (19) compound and its analogues.
Garzino has described an efficient method for the synthesis of (+)-phyltetralin ( 19) derivatives in four steps, with an overall yield of 19% (Scheme 6).A β-ketoester was utilized as a precursor for the synthesis, and oxidative cyclization by manganese(III) was the key step to achieve the synthesis of the target molecule [55].
the substituents on the alkene, as illustrated in Scheme 5 [53].Additionally, a subsequent study by Bar et al. investigated the synthesis of similar quinolone derivatives with various substituents, including alkyl, alkynyl, and aryl groups, resulting in yields ranging from poor to good [54].
Garzino has described an efficient method for the synthesis of (+)-phyltetralin (19) derivatives in four steps, with an overall yield of 19% (Scheme 6).A β-ketoester was utilized as a precursor for the synthesis, and oxidative cyclization by manganese(III) was the key step to achieve the synthesis of the target molecule [55].Scheme 6. (+)-Phyltetralin (19) compound and its analogues.
Magolan and Kerr successfully synthesized the indole derivative (±)-mersicarpine (31) through a synthetic procedure involving a radical addition to the double bond of N-acryl indole (29) to form the tricyclic skeleton (30) (Scheme 9).This step can be considered the key synthesis step.Subsequent reactions were conducted for the formation of other rings, ultimately leading to the successful synthesis of (±)-mersicarpine with a yield of 23.7% from compound (30).The total yield was reported as 11% from the starting compound indoline [58].

Scheme 7. Synthesis of aryltetralin lignan compounds (23a-h).
Thomas et al. described the synthesis of γ-butyrolactones starting from resveratrol analogues featuring catechol and resorcinol substitutes (Scheme 8).Following the synthesis of the corresponding lactone, ε-viniferin, a benzofuran derivative, could be easily obtained.The oxidative lactonization of 24a yielded 25a in 35% yields (as a 3:1 diastereoisomeric mixture) and 26 in 13% yield (1:1 mixture of regioisomers).Conversely, 24b produced 25b and 27 in a 13% yield (1:1 mixture of regioisomers) and diacetate 28 in a 12% yield [57]. Magolan and Kerr successfully synthesized the indole derivative (±)-mersicarpine (31) through a synthetic procedure involving a radical addition to the double bond of N-acryl indole (29) to form the tricyclic skeleton (30) (Scheme 9).This step can be considered the key synthesis step.Subsequent reactions were conducted for the formation of other rings, ultimately leading to the successful synthesis of (±)-mersicarpine with a yield of 23.7% from compound (30).The total yield was reported as 11% from the starting compound indoline [58].Thomas et al. described the synthesis of γ-butyrolactones starting from resveratrol analogues featuring catechol and resorcinol substitutes (Scheme 8).Following the synthesis of the corresponding lactone, ε-viniferin, a benzofuran derivative, could be easily obtained.The oxidative lactonization of 24a yielded 25a in 35% yields (as a 3:1 diastereoisomeric mixture) and 26 in 13% yield (1:1 mixture of regioisomers).Conversely, 24b produced 25b and 27 in a 13% yield (1:1 mixture of regioisomers) and diacetate 28 in a 12% yield [57]. Magolan and Kerr successfully synthesized the indole derivative (±)-mersicarpine (31) through a synthetic procedure involving a radical addition to the double bond of N-acryl indole (29) to form the tricyclic skeleton (30) (Scheme 9).This step can be considered the key synthesis step.Subsequent reactions were conducted for the formation of other rings, ultimately leading to the successful synthesis of (±)-mersicarpine with a yield of 23.7% from compound (30).The total yield was reported as 11% from the starting compound indoline [58].Linker and his colleagues reported the synthesis of key intermediates of 3-deoxy-D-manno-oct-2-ulosonic acid (KDO, 35) (Scheme 10).They utilized an acyclic alkene (32) derived from a carbohydrate as the starting compound, followed by a radical cyclization reaction.Excellent yields were reported.In the radical addition reaction, the addition of 10 equivalents of dimethyl malonate yielded only 33 (Method A).Conversely, without adding dimethyl malonate, a 90% yield of 34 (in a manno:gluco ratio of 68:32), a precursor of KDO, was obtained, along with 33 in a 29% yield (Method B).After obtaining manno-34, it could be easily transformed into KDO [59,60].Linker and his colleagues reported the synthesis of key intermediates of 3-deoxy-D-manno-oct-2-ulosonic acid (KDO, 35) (Scheme 10).They utilized an acyclic alkene (32) derived from a carbohydrate as the starting compound, followed by a radical cyclization reaction.Excellent yields were reported.In the radical addition reaction, the addition of 10 equivalents of dimethyl malonate yielded only 33 (Method A).Conversely, without adding dimethyl malonate, a 90% yield of 34 (in a manno:gluco ratio of 68:32), a precursor of KDO, was obtained, along with 33 in a 29% yield (Method B).After obtaining manno-34, it could be easily transformed into KDO [59,60].
kene (32) derived from a carbohydrate as the starting compound, followed by a radical cyclization reaction.Excellent yields were reported.In the radical addition reaction, the addition of 10 equivalents of dimethyl malonate yielded only 33 (Method A).Conversely, without adding dimethyl malonate, a 90% yield of 34 (in a manno:gluco ratio of 68:32), a precursor of KDO, was obtained, along with 33 in a 29% yield (Method B).After obtaining manno-34, it could be easily transformed into KDO [59,60].Tetrangomycin (36) Tetrangulol (37) Carreno et al. presented a total synthesis review of Angucyclines involving a series of reactions, including free radical cyclization with manganese(III) acetate (Scheme 11).In the total synthesis of the target molecule, benz[a]anthraquinone (40) was obtained with a good yield.Consequently, the ABCD ring skeleton of Angucyclines was formed through the intervention of Mn(III) [61][62][63].
cyclization reaction.Excellent yields were reported.In the radical addition reaction, the addition of 10 equivalents of dimethyl malonate yielded only 33 (Method A).Conversely, without adding dimethyl malonate, a 90% yield of 34 (in a manno:gluco ratio of 68:32), a precursor of KDO, was obtained, along with 33 in a 29% yield (Method B).After obtaining manno-34, it could be easily transformed into KDO [59,60].Tetrangomycin (36) Tetrangulol (37) a: R 1 : H, R  43) derivatives (Scheme 12).The reaction exhibited moderate to good yields with no observable by-products.Additionally, a high degree of stereoselectivity was observed [64].After Yousuf's study, Altun et al. devised a synthesis process for certain carbosugars designed to mimic carbohydrates, with potential applications in drug development.To achieve the target molecules, the key step involved an oxidative radical cyclization reaction with manganese(III) acetate, resulting in the formation of γ-lactone derivatives (46)(47)(48)(49).Subsequent steps included the reduction of 46 and the acetylation of 50, leading to the desired carbosugar molecule 51.The reaction is illustrated in Scheme 13 [65].
After Yousuf's study, Altun et al. devised a synthesis process for certain carbosugars designed to mimic carbohydrates, with potential applications in drug development.To achieve the target molecules, the key step involved an oxidative radical cyclization reaction with manganese(III) acetate, resulting in the formation of γ-lactone derivatives (46)(47)(48)(49).Subsequent steps included the reduction of 46 and the acetylation of 50, leading to the desired carbosugar molecule 51.The reaction is illustrated in Scheme 13 [65].The other C-C bond formation reaction with the assistance of manganese(III) acetate was reported by MacDonald et al. for synthesizing murrayaquinone A (Scheme 14A).This reaction involved the reaction between 2-cyclohexen-1-one (54) and aminoquinone (53) via an oxidative radical reaction facilitated by manganese(III) acetate.The starting material, commercially available 2,4,5-trimethoxybenzaldehyde (52), underwent a three-step process to obtain the target aminobenzoquinone derivative.Subsequently, oxidative radical reaction with 2-cyclohexen-1-one yielded N-benzyl murrayaquinone (55).After an easy debenzylation with triflic acid and trifluoroacetic acid, the target natural compound murrayaquinone A (56) was obtained within five steps with an overall yield of 45%.The mechanism involves radical addition to the alkene to form the C-C bond, as illustrated in Scheme 14B [66].Accordingly, a radical is generated with the aid of Mn(OAc) 3 .This radical then reacts with 53, resulting in the formation of an amino-substituted carbocation 53a.Upon further treatment with additional Mn(OAc) 3 , hydrogen abstraction occurs, leading to the formation of an enamino compound, ultimately yielding compound 55.
murrayaquinone A (56) was obtained within five steps with an overall yield of 45%.The mechanism involves radical addition to the alkene to form the C-C bond, as illustrated in Scheme 14B [66].Accordingly, a radical is generated with the aid of Mn(OAc)3.This radical then reacts with 53, resulting in the formation of an amino-substituted carbocation 53a.Upon further treatment with additional Mn(OAc)3, hydrogen abstraction occurs, leading to the formation of an enamino compound, ultimately yielding compound 55.Scheme 14. (A) The synthesis of murrayaquinone A (56) (B) Manganese(III)-based cyclization reaction of (55).

Mono Cyclizations
White and co-workers reported the synthesis of the furanosesquiterpene hydropallescensin-D via manganese(III) acetate-mediated cyclization (Scheme 15).They initiated the process with starting compound (57) to obtain the dicarbonyl compound (58).Subsequently, they utilized manganese(III) acetate as a radical initiator to yield the bicyclic compound (59), which further proceeded to form the analogue of hydropallescensin-D (62) in six steps with a 34% overall yield [67].The total reaction yield was determined to be 3.2%.
Martinez and Burton also undertook the synthesis of avenaciolide and its derivatives [72].Their approach involved the formation of the fused lactone (76c) as the primary product.To achieve this, they implemented iodine subtraction to the intermediate product to prevent the formation of other undesired products (76a and 76b), resulting in the successful production of the final fused bis lactone (76c) with a yield of 78% (Scheme 19).Subsequently, they applied Krapcho decarboxylation followed by the Johnson protocol to attach the exo-methylene group, leading to the formation of avenaciolide (78a and 78b) and its derivatives.This synthesis procedure was completed in five or six steps, with manganese(III) and iodine-assisted cyclization and lactonization serving as key steps.
Martinez and Burton also undertook the synthesis of avenaciolide and its derivatives [72].Their approach involved the formation of the fused lactone (76c) as the primary product.To achieve this, they implemented iodine subtraction to the intermediate product to prevent the formation of other undesired products (76a and 76b), resulting in the successful production of the final fused bis lactone (76c) with a yield of 78% (Scheme 19).Subsequently, they applied Krapcho decarboxylation followed by the Johnson protocol to attach the exo-methylene group, leading to the formation of avenaciolide (78a and 78b) and its derivatives.This synthesis procedure was completed in five or six steps, with manganese(III) and iodine-assisted cyclization and lactonization serving as key steps.
Martinez and Burton also undertook the synthesis of avenaciolide and its derivatives [72].Their approach involved the formation of the fused lactone (76c) as the primary product.To achieve this, they implemented iodine subtraction to the intermediate product to prevent the formation of other undesired products (76a and 76b), resulting in the successful production of the final fused bis lactone (76c) with a yield of 78% (Scheme 19).Subsequently, they applied Krapcho decarboxylation followed by the Johnson protocol to attach the exo-methylene group, leading to the formation of avenaciolide (78a and 78b) and its derivatives.This synthesis procedure was completed in five or six steps, with manganese(III) and iodine-assisted cyclization and lactonization serving as key steps.
Burton et al. reported another mode of lactonization synthesis containing a [3,2,0]bicyclic core, utilizing manganese(III) acetate in oxidative radical cyclization as a key step [73][74][75].Salinosporamide A, a marine-derived natural product with potential use as a proteasome inhibitor in cancer research, served as the target molecule.Burton initiated the synthesis of salinosporamide A using a commercially available sultam (79).In four steps, amide (±)-80 was obtained, followed by oxidative radical cyclization to yield the [3,3,0]-bicyclic γ-lactone (±)-81 in a high yield with a high diastereomeric ratio (9:1).After nine steps, the target molecule salinosporamide A (82) was achieved in a total of 15 steps with an overall yield of 6%.The cyclization step was deemed most crucial due to the necessity of obtaining the [3,3,0]-bicyclic γ-lactone with good diastereoselectivity (Scheme 20).
Venkateswaran conducted the synthesis of the phenolic sesquiterpene (+)-parvifoline (93), achieving the formation of benzobicyclo[3,3,1]nonane using manganese(III) acetate, followed by the application of a ring-opening protocol (Scheme 22) [77].Typically, the synthesis of this compound involves numerous steps.However, with the assistance of Mn(III), the desired bicyclic compound was obtained in a single step.Venkateswaran devised a meticulous synthetic strategy involving the ring-opening of the bicyclic compound (91) to yield benzocyclooctane (92), an analogue of (+)-parvifoline (93).The literature reports a total of 4 steps for the transformation of ( 92) to (93), achieving an overall yield of 46.4% [78].
synthesis of this compound involves numerous steps.However, with the assistance of Mn(III), the desired bicyclic compound was obtained in a single step.Venkateswaran devised a meticulous synthetic strategy involving the ring-opening of the bicyclic compound (91) to yield benzocyclooctane (92), an analogue of (+)-parvifoline (93).The literature reports a total of 4 steps for the transformation of ( 92) to (93), achieving an overall yield of 46.4% [78].
Lee and co-workers also reported the synthesis of huperzine A (97) [79].This compound features a bicyclic skeleton fused with piperidine-2-one.To achieve this, β-ketoester (94) was alkylated with an appropriate allyl bromide to obtain the allyl product (95).The subsequent radical cyclization of (95) led to the formation of the corresponding huperzine analogue (96) (Scheme 23).Interestingly, the thermodynamically unstable exo-cyclization product (96a) of the huperzine intermediate easily isomerized to the endocyclic compound (96b), the other huperzine analogue.This compound was then converted to Huperzine A using the procedure in the literature, with a total yield of 22% [80].
Lee and co-workers also reported the synthesis of huperzine A (97) [79].This compound features a bicyclic skeleton fused with piperidine-2-one.To achieve this, β-ketoester (94) was alkylated with an appropriate allyl bromide to obtain the allyl product (95).The subsequent radical cyclization of (95) led to the formation of the corresponding huperzine analogue (96) (Scheme 23).Interestingly, the thermodynamically unstable exo-cyclization product (96a) of the huperzine intermediate easily isomerized to the endocyclic compound (96b), the other huperzine analogue.This compound was then converted to Huperzine A using the procedure in the literature, with a total yield of 22% [80].Magolan et al. designed a general and efficient strategy to identify the core structure of tronocarpine, which is particularly appealing.They synthesized a tetracyclic intermediate product with a similar skeleton to tronocarpine using manganese(III) acetate, starting with an N-substituted indole compound (98) (Scheme 24).The addition of a malonate radical, formed by manganese acetate, to the 2-position of the indole resulted in the formation of a tricyclic intermediate (99).The subsequent reduction of the cyano group to an amine, followed by cyclization with an ester, afforded the tetraycyclic core (100) of tronocarpine (101) [81].Magolan et al. designed a general and efficient strategy to identify the core structure of tronocarpine, which is particularly appealing.They synthesized a tetracyclic intermediate product with a similar skeleton to tronocarpine using manganese(III) acetate, starting with an N-substituted indole compound (98) (Scheme 24).The addition of a malonate radical, formed by manganese acetate, to the 2-position of the indole resulted in the formation of a tricyclic intermediate (99).The subsequent reduction of the cyano group to an amine, followed by cyclization with an ester, afforded the tetraycyclic core (100) of tronocarpine (101) [81].
diate product with a similar skeleton to tronocarpine using manganese(III) acetate, starting with an N-substituted indole compound (98) (Scheme 24).The addition of a malonate radical, formed by manganese acetate, to the 2-position of the indole resulted in the formation of a tricyclic intermediate (99).The subsequent reduction of the cyano group to an amine, followed by cyclization with an ester, afforded the tetraycyclic core (100) of tronocarpine (101) [81].
Tejeda et al. conducted a study involving the addition of a radical to indole, resulting in the synthesis of flinderole C (108) through radical intramolecular cyclization, with manganese(III) acetate serving as a radical initiator (Scheme 25).In the initial step, a N-substituted indoline compound (104) was formed by nucleophilic addition to cyclopropane derivatives, employing Yb(OTf)3 as a Lewis catalyst, followed by radical cyclization to produce 1,2-pyrroloindole (105).Following this pivotal step, hydrostannylation and Stille coupling reactions were employed to obtain the flinderol C substructure Scheme 24.Synthesis of tetracyclic core of tronocarpine (101).
Tejeda et al. conducted a study involving the addition of a radical to indole, resulting in the synthesis of flinderole C (108) through radical intramolecular cyclization, with manganese(III) acetate serving as a radical initiator (Scheme 25).In the initial step, a Nsubstituted indoline compound (104) was formed by nucleophilic addition to cyclopropane derivatives, employing Yb(OTf) 3 as a Lewis catalyst, followed by radical cyclization to produce 1,2-pyrroloindole (105).Following this pivotal step, hydrostannylation and Stille coupling reactions were employed to obtain the flinderol C substructure (107).The total synthesis yielded 32%, attributed to the efficiency of the overall synthetic process [82].
Molecules 2024, 29, x FOR PEER REVIEW 15 of 42 (107).The total synthesis yielded 32%, attributed to the efficiency of the overall synthetic process [82].Bhat et al. reported the oxidative cyclization of three substituted indoles, aimed at constructing the core structure of welwitindolinone alkaloids, which possess a bicyclo[4.3.1]decaneskeleton (Scheme 26A).The cyclization predominantly occurred at the C-4 position of the indole when the C-2 position was substituted with chloride, as illustrated in Scheme 26B.Conversely, when the C-2 position was unsubstituted, the cyclization pathway arose at the C-2 position.The synthesis was initiated with compound (115) to construct ketoester (116) (Scheme 26C).The key step involved the radical cyclization by manganese(III) acetate of ( 116) from the C-4 position, yielding the tetracyclic compound (117) with a high yield.Subsequently, oxindole (118) was formed to achieve the core structure of welwitindolinone alkaloids [83].The synthesis of tricyclic natural compounds ialibinone A (126) and ialibinone B (127) (Scheme 28) was also developed by Simpkins and Weller using manganese(III) acetate [86].The starting compound was commercially available phloroglucinol (123), which was subjected to Friedel-Craft to obtain the corresponding product (124) with unsaturated substituents.Then, to convert this substrate to (125) with an acidic proton, it underwent a radical cyclization with Mn(OAc)3 and Cu(OAc)2 to form target ialibinone A (126) and ialibinone B (127) products, respectively.

Lin
and Snider introduced an α'-acetoxidation method utilizing N-trifluoroacetyl-substituted vinylogous amide.They claimed that in the absence of a substituent on the nitrogen atom, instead of α'-acetoxidation, aromatization of the vinylogous amide to pyridine would occur (Scheme 29).To address this, the following methodology was employed: initially, the amide nitrogen was protected with a trifluoroacetyl group, followed by α'-acetoxidation with manganese(III) acetate to yield the acetoxidated compound.Utilizing this approach, they conducted a series of reactions to generate α'-carbon radicals, followed by addition to an alkene to obtain tricyclic derivatives (135) and ( 136), which represented the target sauroine compounds [87].The synthesis of tricyclic natural compounds ialibinone A (126) and ialibinone B (127) (Scheme 28) was also developed by Simpkins and Weller using manganese(III) acetate [86].The starting compound was commercially available phloroglucinol (123), which was subjected to Friedel-Craft to obtain the corresponding product (124) with unsaturated substituents.Then, to convert this substrate to (125) with an acidic proton, it underwent a radical cyclization with Mn(OAc) 3 and Cu(OAc) 2 to form target ialibinone A (126) and ialibinone B (127) products, respectively.The synthesis of tricyclic natural compounds ialibinone A (126) and ialibinone B (127) (Scheme 28) was also developed by Simpkins and Weller using manganese(III) acetate [86].The starting compound was commercially available phloroglucinol (123), which was subjected to Friedel-Craft to obtain the corresponding product (124) with unsaturated substituents.Then, to convert this substrate to (125) with an acidic proton, it underwent a radical cyclization with Mn(OAc)3 and Cu(OAc)2 to form target ialibinone A (126) and ialibinone B (127) products, respectively.

Lin
and Snider introduced an α'-acetoxidation method utilizing N-trifluoroacetyl-substituted vinylogous amide.They claimed that in the absence of a substituent on the nitrogen atom, instead of α'-acetoxidation, aromatization of the vinylogous amide to pyridine would occur (Scheme 29).To address this, the following methodology was employed: initially, the amide nitrogen was protected with a trifluoroacetyl group, followed by α'-acetoxidation with manganese(III) acetate to yield the acetoxidated compound.Utilizing this approach, they conducted a series of reactions to generate α'-carbon radicals, followed by addition to an alkene to obtain tricyclic derivatives (135) and (136), which represented the target sauroine compounds [87].Lin and Snider introduced an α'-acetoxidation method utilizing N-trifluoroacetylsubstituted vinylogous amide.They claimed that in the absence of a substituent on the nitrogen atom, instead of α'-acetoxidation, aromatization of the vinylogous amide to pyridine would occur (Scheme 29).To address this, the following methodology was employed: initially, the amide nitrogen was protected with a trifluoroacetyl group, followed by α'acetoxidation with manganese(III) acetate to yield the acetoxidated compound.Utilizing this approach, they conducted a series of reactions to generate α'-carbon radicals, followed by addition to an alkene to obtain tricyclic derivatives (135) and (136), which represented the target sauroine compounds [87].Scheme 29.Synthesis of sauroine compounds.
Burton and colleagues reported the synthesis of pepluanin A (154) via the oxidative cyclization of pentenyl malonates, with manganese(III) acetate serving as the pivotal step to construct the cyclopentane skeleton.To accomplish this synthesis, they utilized t-butyl acetate and acrolein, followed by alkylation, reduction, and dicarboxylation to obtain the Scheme 29.Synthesis of sauroine compounds.
Burton and colleagues reported the synthesis of pepluanin A (154) via the oxidative cyclization of pentenyl malonates, with manganese(III) acetate serving as the pivotal step to construct the cyclopentane skeleton.To accomplish this synthesis, they utilized t-butyl acetate and acrolein, followed by alkylation, reduction, and dicarboxylation to obtain the Scheme 30.Synthesis of (±)-okicenone (139b) and (±)-aloesaponol III (139c).
Burton and colleagues reported the synthesis of pepluanin A (154) via the oxidative cyclization of pentenyl malonates, with manganese(III) acetate serving as the pivotal step to construct the cyclopentane skeleton.To accomplish this synthesis, they utilized t-butyl acetate and acrolein, followed by alkylation, reduction, and dicarboxylation to obtain the target molecule, a pentenyl malonate derivative (141).Subsequently, they explored the enantioselective synthesis of the cyclopentane core of pepluanin A, following the careful selection of protection groups in the molecule (Scheme 31).This work represents a significant advancement toward the synthesis of the pepluanin A natural compound [89].(−)-Glaucocalyxin A (146), featuring a bicyclo[3,2,1]octane with a three-ring system, was successfully synthesized by Guo et al. via radical cyclization starting from a commercially available compound (143).The key radical cyclization reaction is illustrated in Scheme 32.Following the formation of a carbon radical mediated by manganese(III), an addition to alkyne (144) was implemented to construct the bicyclo[3,2,1]octane core (145), identified as the pivotal step in the synthesis of (−)-glaucocalyxin A. Subsequently, after obtaining (145), 13 additional steps were applied, resulting in an overall yield of 2.3%.Notably, unlike other manganese(III)-mediated radical cyclization reactions, particularly in natural product synthesis, a microwave synthesis was reported to afford a 53% yield [90].

Scheme 32. The synthesis of glaucocalyxin A (146).
Picrotoxane, a sesquiterpene alkaloid group of compounds, was synthesized by Cao et al.The key step involved a radical cyclization reaction to construct the tricyclic compound (149) mediated by manganese(III) acetate, resulting in the formation of picrotoxane derivatives, as illustrated in Scheme 33.The overall yield for (151) was 7.2%, while (152) and (153) were found to be 6.9% and 7.9%, respectively.Additionally, 5-exo radical cyclization intermediates were proposed, and DFT calculations were reported according to the cation intermediate mechanism [91].(−)-Glaucocalyxin A (146), featuring a bicyclo[3,2,1]octane with a three-ring system, was successfully synthesized by Guo et al. via radical cyclization starting from a commercially available compound (143).The key radical cyclization reaction is illustrated in Scheme 32.Following the formation of a carbon radical mediated by manganese(III), an addition to alkyne (144) was implemented to construct the bicyclo[3,2,1]octane core (145), identified as the pivotal step in the synthesis of (−)-glaucocalyxin A. Subsequently, after obtaining (145), 13 additional steps were applied, resulting in an overall yield of 2.3%.Notably, unlike other manganese(III)-mediated radical cyclization reactions, particularly in natural product synthesis, a microwave synthesis was reported to afford a 53% yield [90]. (−)-Glaucocalyxin A (146), featuring a bicyclo[3,2,1]octane with a three-ring system, was successfully synthesized by Guo et al. via radical cyclization starting from a commercially available compound (143).The key radical cyclization reaction is illustrated in Scheme 32.Following the formation of a carbon radical mediated by manganese(III), an addition to alkyne (144) was implemented to construct the bicyclo[3,2,1]octane core (145), identified as the pivotal step in the synthesis of (−)-glaucocalyxin A. Subsequently, after obtaining (145), 13 additional steps were applied, resulting in an overall yield of 2.3%.Notably, unlike other manganese(III)-mediated radical cyclization reactions, particularly in natural product synthesis, a microwave synthesis was reported to afford a 53% yield [90].

Scheme 32. The synthesis of glaucocalyxin A (146).
Picrotoxane, a sesquiterpene alkaloid group of compounds, was synthesized by Cao et al.The key step involved a radical cyclization reaction to construct the tricyclic compound (149) mediated by manganese(III) acetate, resulting in the formation of picrotoxane derivatives, as illustrated in Scheme 33.The overall yield for (151) was 7.2%, while (152) and (153) were found to be 6.9% and 7.9%, respectively.Additionally, 5-exo radical cyclization intermediates were proposed, and DFT calculations were reported according to the cation intermediate mechanism [91].Picrotoxane, a sesquiterpene alkaloid group of compounds, was synthesized by Cao et al.The key step involved a radical cyclization reaction to construct the tricyclic compound (149) mediated by manganese(III) acetate, resulting in the formation of picrotoxane derivatives, as illustrated in Scheme 33.The overall yield for (151) was 7.2%, while (152) and (153) were found to be 6.9% and 7.9%, respectively.Additionally, 5-exo radical cyclization intermediates were proposed, and DFT calculations were reported according to the cation intermediate mechanism [91].

Lam et al. reported the synthesis of a (±)-yezo'otogirin
A natural product starting from commercially available material (154), which was obtained in two steps [92].The key step involved a radical cyclization reaction initiated by manganese(III) acetate, allowing for the efficient preparation of the yezo'otogirin ring system.This synthesis was achieved in conjunction with Cu(OTf)2 as the co-oxidant agent.The entire synthetic pathway comprised nine steps with an overall yield of 3%, while the radical cyclization step alone yielded 29%.To initiate the successful synthesis of (±)-yezo'otogirin A (156), a β-keto ester pre-yezo'otogirin (155) was initially obtained (Scheme 34) [93].

Lam et al. reported the synthesis of a (±)-yezo'otogirin
A natural product starting from commercially available material (154), which was obtained in two steps [92].The key step involved a radical cyclization reaction initiated by manganese(III) acetate, allowing for the efficient preparation of the yezo'otogirin ring system.This synthesis was achieved in conjunction with Cu(OTf) 2 as the co-oxidant agent.The entire synthetic pathway comprised nine steps with an overall yield of 3%, while the radical cyclization step alone yielded 29%.To initiate the successful synthesis of (±)-yezo'otogirin A (156), a β-keto ester pre-yezo'otogirin (155) was initially obtained (Scheme 34) [93].Lam et al. reported the synthesis of a (±)-yezo'otogirin A natural product starting from commercially available material (154), which was obtained in two steps [92].The key step involved a radical cyclization reaction initiated by manganese(III) acetate, allowing for the efficient preparation of the yezo'otogirin ring system.This synthesis was achieved in conjunction with Cu(OTf)2 as the co-oxidant agent.The entire synthetic pathway comprised nine steps with an overall yield of 3%, while the radical cyclization step alone yielded 29%.To initiate the successful synthesis of (±)-yezo'otogirin A (156), a β-keto ester pre-yezo'otogirin (155) was initially obtained (Scheme 34) [93].Scheme 34.The synthesis of (±)-yezo'otogirin A (156).

OTMS
He et al. synthesized the yezo'otogirin natural product (±)-yeto'otogirin C, employing a different approach compared to other radical cyclization reactions.In this method, manganese(III) was utilized along with oxygen for the in situ production of manganese(III).Similar to the synthesis of (±)-yeto'otogirin A, this process also employed the same precursor, β-keto ester (158), in the radical cyclization step.This precursor was synthesized from cyclohexanedione (157).The entire synthesis of (±)-yeto'otogirin C (159) was achieved with an overall yield of 31% and involved four steps (Scheme He et al. synthesized the yezo'otogirin natural product (±)-yeto'otogirin C, employing a different approach compared to other radical cyclization reactions.In this method, manganese(III) was utilized along with oxygen for the in situ production of manganese(III).Similar to the synthesis of (±)-yeto'otogirin A, this process also employed the same precursor, β-keto ester (158), in the radical cyclization step.This precursor was synthesized from cyclohexanedione (157).The entire synthesis of (±)-yeto'otogirin C (159) was achieved with an overall yield of 31% and involved four steps (Scheme 35) [94,95].The synthesis of an abietane derivative diterpene compound was reported by Alvarez-Manzaneda.This synthetic pathway entails multi-step reactions, with the pivotal stage involving the utilization of manganese(III) for cyclization.The reaction sequence is depicted in Scheme 37. Initially, the reaction of β-ketoester (163) with a methylene group He et al. synthesized the yezo'otogirin natural product (±)-yeto'otogirin C, employing a different approach compared to other radical cyclization reactions.In this method, manganese(III) was utilized along with oxygen for the in situ production of manganese(III).Similar to the synthesis of (±)-yeto'otogirin A, this process also employed the same precursor, β-keto ester (158), in the radical cyclization step.This precursor was synthesized from cyclohexanedione (157).The entire synthesis of (±)-yeto'otogirin C (159) was achieved with an overall yield of 31% and involved four steps (Scheme 35) [94,95].The synthesis of an abietane derivative diterpene compound was reported by Alvarez-Manzaneda.This synthetic pathway entails multi-step reactions, with the pivotal stage involving the utilization of manganese(III) for cyclization.The reaction sequence is depicted in Scheme 37. Initially, the reaction of β-ketoester (163) with a methylene group The synthesis of an abietane derivative diterpene compound was reported by Alvarez-Manzaneda.This synthetic pathway entails multi-step reactions, with the pivotal stage involving the utilization of manganese(III) for cyclization.The reaction sequence is depicted in Scheme 37. Initially, the reaction of β-ketoester (163) with a methylene group facilitates cyclization to yield (164) [98].Subsequently, the addition of a methyl group results in (165) via a Grignard reaction, followed by Silyl protection to enable the reduction of the methyl ester group of (166).Upon reduction with LiAlH 4 , the desired diterpene compound, 19-hydroxy ferruginol (167), was produced.
Molecules 2024, 29, x FOR PEER REVIEW 22 of 42 facilitates cyclization to yield (164) [98].Subsequently, the addition of a methyl group results in (165) via a Grignard reaction, followed by Silyl protection to enable the reduction of the methyl ester group of (166).Upon reduction with LiAlH4, the desired diterpene compound, 19-hydroxy ferruginol (167), was produced.
(±)-Spiroaxillarone A belongs to the spirobisnaphthalene compound class, and its synthesis was accomplished through a strategic one-step cycloaddition-oxidation reaction starting from a curcumin (170) derivative.Following the formation of the corresponding spirobisnaphthalene derivative (171), demethylation leads to the production of (±)-spiroaxillarone A (172) with an overall yield of 11%.This procedure exemplifies the efficacy of manganese(III) acetate-based radical cyclization reactions when employing an appropriate starting material to obtain the desired natural compounds (Scheme 39) [101].Paquette and colleagues have detailed a concise pathway for synthesizing (±)-14epiupial (169) utilizing manganese(III) acetate chemistry, with credit given to lactonization in a multi-step synthesis process (Scheme 38).It is observed that only one epimer undergoes cyclization, yielding the corresponding lactone (168a) stereochemically [99].The pivotal stage entails lactonization mediated by manganese(III) acetate, yielding a 68% yield.Following the synthesis of lactone (168a), (±)-14-epiupial (169) was obtained through an additional five steps.Alternatively, Takahashi conducted a comparative study on the synthesis of (+)-upial, an analogue of (±)-14-epiupial, in 15 steps, achieving a total yield of 10% [100].
Molecules 2024, 29, x FOR PEER REVIEW 22 of 42 facilitates cyclization to yield (164) [98].Subsequently, the addition of a methyl group results in (165) via a Grignard reaction, followed by Silyl protection to enable the reduction of the methyl ester group of (166).Upon reduction with LiAlH4, the desired diterpene compound, 19-hydroxy ferruginol (167), was produced.
(±)-Spiroaxillarone A belongs to the spirobisnaphthalene compound class, and its synthesis was accomplished through a strategic one-step cycloaddition-oxidation reaction starting from a curcumin (170) derivative.Following the formation of the corresponding spirobisnaphthalene derivative (171), demethylation leads to the production of (±)-spiroaxillarone A (172) with an overall yield of 11%.This procedure exemplifies the efficacy of manganese(III) acetate-based radical cyclization reactions when employing an appropriate starting material to obtain the desired natural compounds (Scheme 39) [101].
(±)-Spiroaxillarone A belongs to the spirobisnaphthalene compound class, and its synthesis was accomplished through a strategic one-step cycloaddition-oxidation reaction starting from a curcumin (170) derivative.Following the formation of the corresponding spirobisnaphthalene derivative (171), demethylation leads to the production of (±)spiroaxillarone A (172) with an overall yield of 11%.This procedure exemplifies the efficacy of manganese(III) acetate-based radical cyclization reactions when employing an appropriate starting material to obtain the desired natural compounds (Scheme 39) [101].
The sesquiterpene-phenol skeleton serves as the primary framework for various natural products.Crombie et al. synthesized chromanone (174) as a precursor for the production of puupehenol (175a), 15-cyanopuupehenol (175b), 15-oxopuupehenol (175c), and 8-epichromazonarol (175d), compounds renowned for their potential therapeutic effects.Notably, the synthesis of the pivotal compound, chromanone (174), was accomplished in four steps, with the final step involving free radical cyclization facilitated by manganese(III) acetate.However, two methods were explored to obtain compound (174).In the initial approach, copper(II) acetate, in combination with manganese(III) acetate, was utilized at 60 • C, yielding a 25% yield.Conversely, employing only manganese(III) acetate resulted in a 58% yield at 80 • C (Scheme 40) [102].Once (174) was obtained, the subsequent production of target natural products became straightforward, given that the fundamental skeleton was constructed via radical cyclization.The sesquiterpene-phenol skeleton serves as the primary framework for various natural products.Crombie et al. synthesized chromanone (174) as a precursor for the production of puupehenol (175a), 15-cyanopuupehenol (175b), 15-oxopuupehenol (175c), and 8-epichromazonarol (175d), compounds renowned for their potential therapeutic effects.Notably, the synthesis of the pivotal compound, chromanone (174), was accomplished in four steps, with the final step involving free radical cyclization facilitated by manganese(III) acetate.However, two methods were explored to obtain compound (174).In the initial approach, copper(II) acetate, in combination with manganese(III) acetate, was utilized at 60 °C, yielding a 25% yield.Conversely, employing only manganese(III) acetate resulted in a 58% yield at 80 °C (Scheme 40) [102].Once (174) was obtained, the subsequent production of target natural products became straightforward, given that the fundamental skeleton was constructed via radical cyclization.Scheme 39.The synthesis of (±)-spiroaxillarone A (172) natural product.

Tandem Cyclizations
Pettus and his colleagues successfully synthesized tricycloillicinone (178) derivatives by employing tandem cyclization mediated by manganese(III) acetate as a crucial step to generate a radical adduct (177) (Scheme 41).In this procedure, a β-diketone (176) underwent a tandem cyclization reaction, yielding (177) with an impressive yield of 78%, which is notably high for reactions of this type.It has been reported that the cyclization reaction occurs subsequent to the cleavage of the silyl enol ether, leading to the formation of the β-diketone.The overall yield was reported to be 8.1% [103].

Tandem Cyclizations
Pettus and his colleagues successfully synthesized tricycloillicinone (178) derivatives by employing tandem cyclization mediated by manganese(III) acetate as a crucial step to generate a radical adduct (177) (Scheme 41).In this procedure, a β-diketone (176) underwent a tandem cyclization reaction, yielding (177) with an impressive yield of 78%, which is notably high for reactions of this type.It has been reported that the cyclization reaction occurs subsequent to the cleavage of the silyl enol ether, leading to the formation of the β-diketone.The overall yield was reported to be 8.1% [103].Lee and his co-workers documented a total synthesis of (−)-estafiatin (179) and (+)cladantholide (180), sesquiterpene lactones, as outlined in Scheme 42A.The formation of the seven-membered ring (182) involved a tandem cyclization of dialkene (181), proceeding from a 5-exo lactonization, followed by a 7-endo cyclization (Scheme 42B,C).In addition to manganese(III) acetate, copper(II) acetate was employed to facilitate radical cyclization, yielding a diastereomeric ratio of 3:1.The reported yield for this pivotal step was 65%, representing a critical advancement towards efficient product synthesis [104].
Snider also presented a synthetic pathway for the production of (±)-podocarpic acid analogue (191) through the application of free radical chemistry mediated by manganese(III) acetate (Scheme 44).The pivotal stage involved intramolecular tandem cyclization to form a fused tricyclic intermediate (190).Following this, Clemmensen reduction using Zn/HCl was conducted to yield the corresponding product, (±)-podocarpic acid analogue (191) [106].

OH
Spongiadiol (204), epispongidiol (205) and isospongidiol (206) compounds are members of the furanoditerpene class, and were isolated from a marine sponge Spongia Linnaeus (Scheme 47A).The most significant part of the synthesis of these compounds is the formation of tricyclic ring.Zoretic and co-workers suggested tandem cyclization to form tricyclic ring starting from an appropriate isolated triene compound (207) (Scheme 47B).After deriving the tricyclic skeleton (209) by a tandem cyclization of (208) via manganese(III), a multi-step reaction was conducted to obtain a spongian skeleton (210) in seven steps, reaching a 42.2% total yield.Having obtained (210), they carried on the synthesis of isospongiadiaol, thus achieving a racemic d,l-isospongiadiol (206) mixture with five additional steps [109].

Zoretic
et al. presented a synthetic approach to produce d,l-5α-D-homoandrostane-3,17a-dione (203).The pivotal step involved a tandem cyclization of tetraene (201) by inducing radical formation on the methyl β-keto ester, resulting in the formation of the tetracyclic compound (202) (Scheme 46).Following this cyclization step, additional carefully designed stereoselective methods were employed to attain the desired steroid compound (203) [108].Spongiadiol (204), epispongidiol (205) and isospongidiol (206) compounds are members of the furanoditerpene class, and were isolated from a marine sponge Spongia Linnaeus (Scheme 47A).The most significant part of the synthesis of these compounds is the formation of tricyclic ring.Zoretic and co-workers suggested tandem cyclization to form tricyclic ring starting from an appropriate isolated triene compound (207) (Scheme 47B).After deriving the tricyclic skeleton (209) by a tandem cyclization of (208) via manganese(III), a multi-step reaction was conducted to obtain a spongian skeleton (210) in seven steps, reaching a 42.2% total yield.Having obtained (210), they carried on the synthesis of Zoretic et al. achieved a synthetic pathway for the production of d,l-5α-pregnane steroid analogue D-homosteroid (216) via a tandem cyclization reaction (Scheme 48).Initially, they commenced the synthesis by constructing the key compound triene (213) through a three-step process.An oxidative tandem cyclization of triene (213) yielded the corresponding tetracyclic isomer (214) with a yield of 61%, along with the tetracyclic acetate derivative (215) in a 5% yield.Following the acquisition of tetracyclic (214), they transformed it into the precursor of 5α-pregnanes, D-homosteroid (216), through a three-step sequence, achieving a total yield of 46% [110].Zoretic et al. achieved a synthetic pathway for the production of d,l-5α-pregnane steroid analogue D-homosteroid (216) via a tandem cyclization reaction (Scheme 48).Initially, they commenced the synthesis by constructing the key compound triene (213) through a threestep process.An oxidative tandem cyclization of triene (213) yielded the corresponding tetracyclic isomer (214) with a yield of 61%, along with the tetracyclic acetate derivative (215) in a 5% yield.Following the acquisition of tetracyclic (214), they transformed it into the precursor of 5α-pregnanes, D-homosteroid (216), through a three-step sequence, achieving a total yield of 46% [110].Meng reported a comprehensive synthesis study showcasing a tandem cyclization of a β-keto ester (218) to yield a single diastereomer trans-decalin (219) with a 48% yield, facilitated by Cu(OAc)2 in DMSO (Scheme 49).Subsequently, in the following reactions, oridamcin A and oridamycin B were synthesized.Decalin (219) played a crucial role as a key intermediate, enabling the entire reaction process, as the primary skeleton of oridamycin (220) was formed through free radical tandem cyclization [111].Similarly, Trotta also presented a comparable study detailing the production of oridamycin A (220a) and oridamycin B (220b) by synthesizing trans-decalin using manganese(III) acetate [112].Meng reported a comprehensive synthesis study showcasing a tandem cyclization of a β-keto ester (218) to yield a single diastereomer trans-decalin (219) with a 48% yield, facilitated by Cu(OAc) 2 in DMSO (Scheme 49).Subsequently, in the following reactions, oridamcin A and oridamycin B were synthesized.Decalin (219) played a crucial role as a key intermediate, enabling the entire reaction process, as the primary skeleton of oridamycin (220) was formed through free radical tandem cyclization [111].Similarly, Trotta also presented a comparable study detailing the production of oridamycin A (220a) and oridamycin B (220b) by synthesizing trans-decalin using manganese(III) acetate [112].
facilitated by Cu(OAc)2 in DMSO (Scheme 49).Subsequently, in the following reactions, oridamcin A and oridamycin B were synthesized.Decalin (219) played a crucial role as a key intermediate, enabling the entire reaction process, as the primary skeleton of oridamycin (220) was formed through free radical tandem cyclization [111].Similarly, Trotta also presented a comparable study detailing the production of oridamycin A (220a) and oridamycin B (220b) by synthesizing trans-decalin using manganese(III) acetate [112].Yang and colleagues pursued the synthesis of (−)-triptolide ( 221), (−)-triptonide (222), and (+)-triptophenolide (223) utilizing manganese(III) acetate chemistry (Scheme 50).Additionally, they revealed the impact of lanthanide triflates as chelating agents to enhance stereoselectivity [113,114].Their study involved the utilization of a range of lanthanide triflates such as Yb(OTf)3, Er(OTf)3, Sm(OTf)3, Y(OTf)3, and Pr(OTf)3 Lewis acids, which not only accelerated the reaction but also provided improved stereoselectivity with higher yields.The effect of lanthanide triflates was attributed to the coordination of bidentate carbonyl groups in the radical compound formed in the intermediate structure.This coordination facilitated radical addition from one side, thereby enhancing diastereoselectivity. Furthermore, to achieve the enantioselective synthesis of the target molecules, Yang employed (−)-8-phenylmenthol.The tandem oxidative cyclization of (+)-8-phenylmethylester (224) resulted in the formation of (225) with a 38:1 diastereomeric ratio, followed by the transformation of ( 225) to (225a) in three steps with a yield of 55.7%.The demethylation of (225a) readily furnished (+)-triptophenolide (223) in a 98% yield [115].Snider et al. reported the synthesis of 15-acetoxypallescensin-A (228) in just five steps, starting from commercially available 3-chloromethylfuran, achieving an overall yield of 16.3% [116].In Scheme 51, the reaction proceeds through an intramolecular tandem cyclization, with manganese(III)-assisted radical cyclization being the pivotal step.When compared to the study by Zoretic, which involved the synthesis of 15-acetoxypallescensin-A in 12 steps with an overall yield of 1.3%, Snider's approach not Snider et al. reported the synthesis of 15-acetoxypallescensin-A (228) in just five steps, starting from commercially available 3-chloromethylfuran, achieving an overall yield of 16.3% [116].In Scheme 51, the reaction proceeds through an intramolecular tandem cyclization, with manganese(III)-assisted radical cyclization being the pivotal step.When compared to the study by Zoretic, which involved the synthesis of 15-acetoxypallescensin-A in 12 steps with an overall yield of 1.3%, Snider's approach not only reduced the number of synthesis steps, but also resulted in an increased overall yield [117].
only reduced the number of synthesis steps, but also resulted in an increased overall yield [117].Barraro and his research group successfully synthesized the bicyclic core structure of wentilactone B (231), utilizing a manganese(III)-induced tandem cyclization procedure, followed by the formation of the tetracyclic podolactone skeleton via Pd(II) bislactonization (Scheme 52).Commencing from commercially available geraniol (229), a 3.5% yield was achieved for the synthesis of (231), with a particularly notable tandem cyclization yield of 68% facilitated by Mn(OAc)3.The total synthesis yield was calculated to be 0.3% [118].(±)-Norascyronones A (237) and (±)-norascyronones B (238) contain four condensed cyclic structures with a five-stereogenic center.Cao et al. reported the synthesis of these natural products by radical cyclization via manganese(III) acetate.To achieve the production, they began with the synthesis of diketone (234) at first (Scheme 53).After deriving the appropriate starting compound diketone with an overall yield of 17.4% in three steps, a tandem cyclization was applied to derive (236) from Mn(OAc)3/Cu(OAc)2 in EtOH.This step was mentioned as the key step for the synthesis, and afterwards (±)-norascyronones A (237) and (±)-norascyronones B (238) were obtained in seven steps with a 16.4% overall yield.Also note that norascyronones C (235) was obtained from diketone (234) in a 44% yield [119].Barraro and his research group successfully synthesized the bicyclic core structure of wentilactone B (231), utilizing a manganese(III)-induced tandem cyclization procedure, followed by the formation of the tetracyclic podolactone skeleton via Pd(II) bislactonization (Scheme 52).Commencing from commercially available geraniol (229), a 3.5% yield was achieved for the synthesis of (231), with a particularly notable tandem cyclization yield of 68% facilitated by Mn(OAc) 3 .The total synthesis yield was calculated to be 0.3% [118].only reduced the number of synthesis steps, but also resulted in an increased overall yield [117].Barraro and his research group successfully synthesized the bicyclic core structure of wentilactone B (231), utilizing a manganese(III)-induced tandem cyclization procedure, followed by the formation of the tetracyclic podolactone skeleton via Pd(II) bislactonization (Scheme 52).Commencing from commercially available geraniol (229), a 3.5% yield was achieved for the synthesis of (231), with a particularly notable tandem cyclization yield of 68% facilitated by Mn(OAc)3.The total synthesis yield was calculated to be 0.3% [118].(±)-Norascyronones A (237) and (±)-norascyronones B (238) contain four condensed cyclic structures with a five-stereogenic center.Cao et al. reported the synthesis of these natural products by radical cyclization via manganese(III) acetate.To achieve the production, they began with the synthesis of diketone (234) at first (Scheme 53).After deriving the appropriate starting compound diketone with an overall yield of 17.4% in three steps, a tandem cyclization was applied to derive (236) from Mn(OAc)3/Cu(OAc)2 in EtOH.This step was mentioned as the key step for the synthesis, and afterwards (±)-norascyronones A (237) and (±)-norascyronones B (238) were obtained in seven steps with a 16.4% overall yield.Also note that norascyronones C (235) was obtained from diketone (234) in a 44% yield [119]. (±)-Norascyronones A (237) and (±)-norascyronones B (238) contain four condensed cyclic structures with a five-stereogenic center.Cao et al. reported the synthesis of these natural products by radical cyclization via manganese(III) acetate.To achieve the production, they began with the synthesis of diketone (234) at first (Scheme 53).After deriving the appropriate starting compound diketone with an overall yield of 17.4% in three steps, a tandem cyclization was applied to derive (236) from Mn(OAc) 3 /Cu(OAc) 2 in EtOH.This step was mentioned as the key step for the synthesis, and afterwards (±)-norascyronones A (237) and (±)-norascyronones B (238) were obtained in seven steps with a 16.4% overall yield.Also note that norascyronones C (235) was obtained from diketone (234) in a 44% yield [119].Scheme 53.The synthesis of (±)-norascyronones A (237) and (±)-norascyronones B (238).
Finally, last but not the least, Mitasev et al. employed phloroglucinol substrates in oxidative [4 + 2] cycloaddition reactions via tandem cyclization mediated by manganese(III) chemistry [39].The conversion mechanism is elucidated in Scheme 54.Despite its apparent complexity, a detailed review reveals that all reactions involve radical additions to alkenes to form cyclizations.In the initial step, a phloroglucinol derivative (239) forms a manganese(III)-enol structure (241), where a radical is generated on C-3, followed by addition to the closest alkene to construct (242).Subsequently, the radical intermediate again attacks the alkene to form the C-5 radical adduct (243).This C-5 radical then forms a pentacyclic intermediate (244), followed by radical addition to the allyl group and reaction with Cu(II), ultimately resulting in the loss of Cu(I) to construct the final compound (240).Upon overall investigation of the reaction, a [4 + 2] cycloaddition and 5-exo radical cyclizations were observed in the final product, with a yield of 76%.Scheme 53.The synthesis of (±)-norascyronones A (237) and (±)-norascyronones B (238).
Finally, last but not the least, Mitasev et al. employed phloroglucinol substrates in oxidative [4 + 2] cycloaddition reactions via tandem cyclization mediated by manganese(III) chemistry [39].The conversion mechanism is elucidated in Scheme 54.Despite its apparent complexity, a detailed review reveals that all reactions involve radical additions to alkenes to form cyclizations.In the initial step, a phloroglucinol derivative (239) forms a manganese(III)enol structure (241), where a radical is generated on C-3, followed by addition to the closest alkene to construct (242).Subsequently, the radical intermediate again attacks the alkene to form the C-5 radical adduct (243).This C-5 radical then forms a pentacyclic intermediate (244), followed by radical addition to the allyl group and reaction with Cu(II), ultimately resulting in the loss of Cu(I) to construct the final compound (240).Upon overall investigation of the reaction, a [4 + 2] cycloaddition and 5-exo radical cyclizations were observed in the final product, with a yield of 76%.
Scheme 55.Synthesis of natural products by manganese(III) radical chemistry.

Oxidation Reactions
Manganese(III) acetate can also function as an oxidation agent.Shing reported the synthesis of enones (261) using steroids (260), where the steroids act as bioactive agents under a nitrogen atmosphere (Scheme 57).Reaction yields were reported to range from 70% to 99%.Conversely, allylic oxidation was employed with simple alkenes (262) under an oxygen atmosphere, resulting in the formation of enone compounds (263) with good yields ranging from 52% to 74% [122].

Oxidation Reactions
Manganese(III) acetate can also function as an oxidation agent.Shing reported the synthesis of enones (261) using steroids (260), where the steroids act as bioactive agents under a nitrogen atmosphere (Scheme 57).Reaction yields were reported to range from 70% to 99%.Conversely, allylic oxidation was employed with simple alkenes (262) under an oxygen atmosphere, resulting in the formation of enone compounds (263) with good yields ranging from 52% to 74% [122].Scheme 57.Allylic oxidation of steroids and simple alkenes with manganese(III) acetate.
The oxidation of phenol to quinone may be achieved using manganese(III) acetate in H2SO4/CH3CN at room temperature.Fukuyama reported the synthesis of (±)-cyanocycline A (265).In the final step of the total synthesis, the phenol group of (264) was converted into the quinone (265) with a 55% yield by using excess Mn(OAc)3 (Scheme 58) [123].The oxidation of phenol to quinone may be achieved using manganese(III) acetate in H 2 SO 4 /CH 3 CN at room temperature.Fukuyama reported the synthesis of (±)-cyanocycline A (265).In the final step of the total synthesis, the phenol group of (264) was converted into the quinone (265) with a 55% yield by using excess Mn(OAc) 3 (Scheme 58) [123].
Scheme 57.Allylic oxidation of steroids and simple alkenes with manganese(III) acetate.

Acetoxidation
Demir and colleagues initially introduced a one-step method to obtain α'-acetoxidated enones, utilizing manganese(III) acetate or manganese(II) salts of corresponding carboxylic acids [32].This one-step α'-acetoxidation has been widely employed in various syntheses to selectively substitute alcohol groups in cyclic structures with enone functionality.This method operates via a radical mechanism.Kawada and co-workers utilized manganese(III) acetate to protect and obtain the target molecule at the C-11 carbon (274) by transforming it into (274a) through acetoxidation in the enantioselective total synthesis of (+)-picrasin B (275) (Scheme 61) [126].

Acetoxidation
Demir and colleagues initially introduced a one-step method to obtain α'-acetoxidated enones, utilizing manganese(III) acetate or manganese(II) salts of corresponding carboxylic acids [32].This one-step α'-acetoxidation has been widely employed in various syntheses to selectively substitute alcohol groups in cyclic structures with enone functionality.This method operates via a radical mechanism.Kawada and co-workers utilized manganese(III) acetate to protect and obtain the target molecule at the C-11 carbon (274) by transforming it into (274a) through acetoxidation in the enantioselective total synthesis of (+)-picrasin B (275) (Scheme 61) [126].

Halogen Transfer
Rao et al. reported the synthesis of fredericamycin A, a spiro-natural compound with a spiro [4.4]nonane skeleton (Scheme 62), utilizing free radical cyclization.They employed a radical halogen transfer mechanism within manganese(III) acetate, followed by reductive elimination to construct the spiro [4.4]nonane skeleton (281).A range of starting molecules was investigated to understand their effects [127].The radical halogen transfer mechanism was illustrated in Scheme 62. Halogen transfer facilitated the formation of the spiro-system, yielding only one isomer.According to the authors, this procedure enabled the synthesis of fredericamycin A (282).

Halogen Transfer
Rao et al. reported the synthesis of fredericamycin A, a spiro-natural compound with a spiro [4.4]nonane skeleton (Scheme 62), utilizing free radical cyclization.They employed a radical halogen transfer mechanism within manganese(III) acetate, followed by reductive elimination to construct the spiro [4.4]nonane skeleton (281).A range of starting molecules was investigated to understand their effects [127].The radical halogen transfer mechanism was illustrated in Scheme 62. Halogen transfer facilitated the formation of the spiro-system, yielding only one isomer.According to the authors, this procedure enabled the synthesis of fredericamycin A (282).

Polymerization
Hwang et al. conducted the polymerization of a derivative of lignin, polyguaiacol, using manganese(III) acetate starting from guaiacol.The reaction was carried out in water and other organic solvents miscible in water, and the effects on polymerization yields were compared [45].Selective radical polymerization occurred in the synthesis, resulting in a higher yield compared to other polymerization methods.An average molecular weight of 1460 g/mol was reported in the acetonitrile-water solvent solution with an 88% yield, which is significantly higher than those obtained in other organic solvents.In addition to the polymerization of guaiacol, other oxidation products were also observed to be formed.

Conclusions
In conclusion, the synthesis of natural compounds poses significant challenges due

Polymerization
Hwang et al. conducted the polymerization of a derivative of lignin, polyguaiacol, using manganese(III) acetate starting from guaiacol.The reaction was carried out in water and other organic solvents miscible in water, and the effects on polymerization yields were compared [45].Selective radical polymerization occurred in the synthesis, resulting in a higher yield compared to other polymerization methods.An average molecular weight of 1460 g/mol was reported in the acetonitrile-water solvent solution with an 88% yield, which is significantly higher than those obtained in other organic solvents.In addition to the polymerization of guaiacol, other oxidation products were also observed to be formed.

Conclusions
In conclusion, the synthesis of natural compounds poses significant challenges due to their inherent complexity, often resulting in variations in structure and configuration.Many researchers aim to approximate the final structure in their synthesis attempts, recognizing the difficulty of achieving exact replications consistently.In my assessment, the most challenging aspect of synthesis lies in achieving the appropriate configuration during cyclization.Specifically, manganese(III) acetate not only facilitates cyclization, but also enables stereocontrolled synthesis [113].
Additionally, utilizing manganese(III) acetate proves to be a valuable tool in this regard, as it not only facilitates intramolecular and intermolecular cyclization, but also enables aromatization, polymerization, halogen transfer, acetoxidation, oxidation, and rearrangement reactions, streamlining the process and yielding higher success rates compared to alternative techniques.
Cyclization with manganese(III) acetate typically reduces the number of steps required compared to alternative techniques such as nucleophilic or electrophilic addition.Moreover, manganese(III) acetate cyclization tends to yield higher yields compared to other methods.In summary, radical oxidation reactions based on manganese(III) acetate represent a significant synthetic advancement in organic chemistry.Overall, manganese(III) acetate offers a versatile and efficient approach to forming C-C bonds, indicating a significant advancement in organic chemistry through radical oxidation reactions.

Scheme 1 .
Scheme 1. (A) Crystal structure of manganese(III) acetate and (B) single electron transfer reaction mechanism with manganese(III) acetate.

Scheme 1 .
Scheme 1. (A) Crystal structure of manganese(III) acetate and (B) single electron transfer reaction mechanism with manganese(III) acetate.

Scheme 10 .
Scheme 10.The synthesis of key intermediates of 3-deoxy-D-manno-oct-2-ulosonic acid(35).Carreno et al. presented a total synthesis review of Angucyclines involving a series of reactions, including free radical cyclization with manganese(III) acetate (Scheme 11).In the total synthesis of the target molecule, benz[a]anthraquinone (40) was obtained with a good yield.Consequently, the ABCD ring skeleton of Angucyclines was formed through the intervention of Mn(III)[61][62][63].

Scheme 10 .
Scheme 10.The synthesis of key intermediates of 3-deoxy-D-manno-oct-2-ulosonic acid(35).Carreno et al. presented a total synthesis review of Angucyclines involving a series of reactions, including free radical cyclization with manganese(III) acetate (Scheme 11).In the total synthesis of the target molecule, benz[a]anthraquinone (40) was obtained with a good yield.Consequently, the ABCD ring skeleton of Angucyclines was formed through the intervention of Mn(III)[61][62][63].

Scheme 12 .
Scheme 12. Synthesis of carbohydrate-based γ-butyrolactones.After Yousuf's study, Altun et al. devised a synthesis process for certain carbosugars designed to mimic carbohydrates, with potential applications in drug development.To achieve the target molecules, the key step involved an oxidative radical cyclization reaction with manganese(III) acetate, resulting in the formation of γ-lactone derivatives (46-49).Subsequent steps included the reduction of 46 and the acetylation of 50, leading to Scheme 12. Synthesis of carbohydrate-based γ-butyrolactones.

Scheme 25 .
Scheme 25. (A) Synthesis of (104) at initial step (B) Synthesis of flinderol C (108) by intramolecular radical addition reaction.Bhat et al. reported the oxidative cyclization of three substituted indoles, aimed at constructing the core structure of welwitindolinone alkaloids, which possess a bicyclo[4.3.1]decaneskeleton (Scheme 26A).The cyclization predominantly occurred at the C-4 position of the indole when the C-2 position was substituted with chloride, as illus-

Scheme 46 .
Scheme 46.The key step in the synthesis of D-homoandrostane derivative (203).

Scheme 46 .
Scheme 46.The key step in the synthesis of D-homoandrostane derivative (203).
Molecules 2024, 29, x FOR PEER REVIEW 19 of 42 target molecule, a pentenyl malonate derivative (141).Subsequently, they explored the enantioselective synthesis of the cyclopentane core of pepluanin A, following the careful selection of protection groups in the molecule (Scheme 31).This work represents a significant advancement toward the synthesis of the pepluanin A natural compound [89].
Scheme 31.The synthesis pepluanin A derivatives.
Molecules 2024, 29, x FOR PEER REVIEW 19 of 42 target molecule, a pentenyl malonate derivative (141).Subsequently, they explored the enantioselective synthesis of the cyclopentane core of pepluanin A, following the careful selection of protection groups in the molecule (Scheme 31).This work represents a significant advancement toward the synthesis of the pepluanin A natural compound [89].
Scheme 31.The synthesis pepluanin A derivatives.
Synthesis of oridamycin family with manganese(III) acetate as a key step.Synthesis of oridamycin family with manganese(III) acetate as a key step.
Scheme 55.Synthesis of natural products by manganese(III) radical chemistry.