key: cord-0700511-tloiq910 authors: Yaremenko, Ivan A.; Radulov, Peter S.; Belyakova, Yulia Yu.; Fomenkov, Dmitriy I.; Tsogoeva, Svetlana B.; Terent’ev, Alexander O. title: Lewis Acids and Heteropoly Acids in the Synthesis of Organic Peroxides date: 2022-04-13 journal: Pharmaceuticals (Basel) DOI: 10.3390/ph15040472 sha: 63388e75e53237f82ae81e0817b68446ebfb85a1 doc_id: 700511 cord_uid: tloiq910 Organic peroxides are an important class of compounds for organic synthesis, pharmacological chemistry, materials science, and the polymer industry. Here, for the first time, we summarize the main achievements in the synthesis of organic peroxides by the action of Lewis acids and heteropoly acids. This review consists of three parts: (1) metal-based Lewis acids in the synthesis of organic peroxides; (2) the synthesis of organic peroxides promoted by non-metal-based Lewis acids; and (3) the application of heteropoly acids in the synthesis of organic peroxides. The information covered in this review will be useful for specialists in the field of organic synthesis, reactions and processes of oxygen-containing compounds, catalysis, pharmaceuticals, and materials engineering. Organic peroxides, due to their unique ability to form O-centered radicals via cleavage of the O-O bond, are widely used in polymer chemistry. In particular, dicumyl peroxide, dibenzoyl peroxide, 1,1-di-tert-butyl hydroperoxy cyclohexane, tert-butyl hydroperoxide, which are convenient in handling, have found application as initiators for low-temperature polymerization of styrene, butadiene, vinyl chloride, acrylates, ethylene [1, 2] , and as reagents for vulcanization of rubbers [3, 4] . According to the latest research, the global organic peroxide market size was around US $2 billion in 2020 [5] . Despite the successful application of peroxides in the polymer industry, it was believed for a long time that the application of organic peroxides as drugs was not possible due to their low stability and the generation of hazardous reactive oxygen species, which can quickly and nonspecifically interact with biomolecules. Discovery of the natural peroxide Artemisinin (Qinghaosu) and its outstanding antimalarial activity [6, 7] in 1972, showed that cyclic peroxides can be used in medicine as drugs. In 2015, Youyou Tu was awarded the Nobel Prize "for her discoveries regarding a new therapy for malaria" [8, 9] . Drugs based on Artemisinin and its semisynthetic analogues are recommended by WHO as one of the most effective agents for the treatment of malaria ( Figure 1 ) [10] [11] [12] . To overcome the emerging problem of drug resistance and to further improve the efficacy of Artemisinin, numerous derivatives of this unique natural product have recently been designed, synthesized and evaluated for biological activities [13, 14] . [50] [51] [52] , [4 + 2] , the cycloaddition of singlet oxygen to dienes [53, 54] , the peroxysilylation of alkenes by the Isayama-Mukayama reaction [55] [56] [57] [58] [59] [60] [61] [62] , the cyclization of unsaturated hydroperoxides by the Kobayashi reaction [63] [64] [65] , processes with the participation of destabilized peroxycarbenium ions [66] [67] [68] , the ozonolysis of alkenes [69] [70] [71] [72] [73] [74] , the nucleophilic addition of hydrogen peroxide to carbonyl compounds and their analogs catalyzed by acids [75] [76] [77] [78] [79] [80] [81] [82] [83] [84] [85] [86] [87] [88] [89] [90] [91] , and the ring opening reaction of Donor-Acceptor cyclopropanes with alkyl hydroperoxides [92] . The most affordable starting materials for the synthesis of organic peroxides are carbonyl compounds and hydrogen peroxide. This review, which covers the major achievements in the synthesis of organic peroxides ( Figure 2 ) using Lewis acids and heteropoly acids, consists of three parts: (1) metalbased Lewis acids in the synthesis of organic peroxides; (2) synthesis of organic peroxides promoted by non-metal-based Lewis acids; (3) application of heteropoly acids in the syn- The growing demand for Artemisinin has pushed scientists to develop its total synthesis. The disadvantage of the available methods for synthesis of Artemisinin is the low overall yield, which prompted the search for synthetic peroxides with antimalarial properties. Currently, the most promising classes of synthetic peroxides are 1,2-dioxolanes, 1,2,4-trioxolanes (ozonides), 1,2-dioxanes, 1,2,4-trioxanes, and 1,2,4,5-tetraoxanes. Representatives of these families have demonstrated antimalarial [10, 11, 15] , anthelmintic [16] [17] [18] [19] [20] [21] [22] [23] [24] [25] [26] [27] [28] , antitumor [29, 30] , anti-tuberculosis [31] [32] [33] , growth regulatory [34] [35] [36] and fungicidal activity [37] [38] [39] [40] . In 2012, arterolane (ozonide OZ277) was the first synthetic peroxide to be approved for treatment of malaria in medical practice ( Figure 1 ) [41] [42] [43] [44] [45] . Ozonide artefenomel (OZ 439) is a second generation clinical candidate against malaria [46] . Very recently, it has been shown that arterolane exhibits in vitro activity against α-coronavirus NL63 and β-coronaviruses OC43, and SARS-CoV-2 [47, 48] . Artemisinin and its derivatives were also found to be active against SARS-CoV-2 in vitro as well [49] . Modern approaches to the synthesis of organic peroxides are based upon the use of oxygen, ozone, and hydrogen peroxide as sources of the O-O group. The most common methods for the construction of the O-O group are the ene reaction of singlet oxygen with alkenes [50] [51] [52] , [4 + 2] , the cycloaddition of singlet oxygen to dienes [53, 54] , the peroxysilylation of alkenes by the Isayama-Mukayama reaction [55] [56] [57] [58] [59] [60] [61] [62] , the cyclization of unsaturated hydroperoxides by the Kobayashi reaction [63] [64] [65] , processes with the participation of destabilized peroxycarbenium ions [66] [67] [68] , the ozonolysis of alkenes [69] [70] [71] [72] [73] [74] , the nucleophilic addition of hydrogen peroxide to carbonyl compounds and their analogs catalyzed by acids [75] [76] [77] [78] [79] [80] [81] [82] [83] [84] [85] [86] [87] [88] [89] [90] [91] , and the ring opening reaction of Donor-Acceptor cyclopropanes with alkyl hydroperoxides [92] . The most affordable starting materials for the synthesis of organic peroxides are carbonyl compounds and hydrogen peroxide. This review, which covers the major achievements in the synthesis of organic peroxides ( Figure 2 ) using Lewis acids and heteropoly acids, consists of three parts: (1) metal-based Lewis acids in the synthesis of organic peroxides; (2) synthesis of organic peroxides promoted by non-metal-based Lewis acids; (3) application of heteropoly acids in the synthesis of organic peroxides. This review provides information that will be useful to specialists in the field of organic synthesis, catalysis, pharmaceuticals, and the polymer industry. thesis of organic peroxides. This review provides information that will be useful to specialists in the field of organic synthesis, catalysis, pharmaceuticals, and the polymer industry. Traditionally, strong Bronsted acids play the role of a catalyst in the synthesis of organic peroxides. The use of metal-based Lewis acids for the synthesis of peroxides is a surprising phenomenon. Generally, peroxides decompose or rearrange under the action of transition metal salts [93, 94] . However, some metal-based Lewis acids, on the contrary, promote the assembly of peroxides. In this section, we summarized the approaches on the synthesis of 1,2-dioxolanes, 1,2-dioxanes, 1,2-dioxepanes, 1,2-dioxocanes, 1,2,4,5-tetraoxanes, 1,2,4,5,7,8-hexaoxonanes, and acyclic peroxides under the action of metal-based Lewis acids. The first example of selective synthesis of organic peroxide using a metal-based Lewis acid SnCl4 as a catalyst goes back to 1950 [95] . Bartlett Traditionally, strong Bronsted acids play the role of a catalyst in the synthesis of organic peroxides. The use of metal-based Lewis acids for the synthesis of peroxides is a surprising phenomenon. Generally, peroxides decompose or rearrange under the action of transition metal salts [93, 94] . However, some metal-based Lewis acids, on the contrary, promote the assembly of peroxides. In this section, we summarized the approaches on the synthesis of 1,2-dioxolanes, 1,2-dioxanes, 1,2-dioxepanes, 1,2-dioxocanes, 1,2,4,5-tetraoxanes, 1,2,4,5,7,8hexaoxonanes, and acyclic peroxides under the action of metal-based Lewis acids. The first example of selective synthesis of organic peroxide using a metal-based Lewis acid SnCl 4 as a catalyst goes back to 1950 [95] . Bartlett In 1959, R. Huttel et al. found that benzyl hydroperoxide 4 is formed by treating benzyl chloride 3 with an excess of hydrogen peroxide (90% aq. solution) in the presence of tin (IV) chloride as a catalyst [96] . The yield of benzyl hydroperoxide 4 was 23% (Scheme 2). In 1959, R. Huttel et al. found that benzyl hydroperoxide 4 is formed by treating benzyl chloride 3 with an excess of hydrogen peroxide (90% aq. solution) in the presence of tin (IV) chloride as a catalyst [96] . The yield of benzyl hydroperoxide 4 was 23% (Scheme 2). Scheme 1. Synthesis of hydroperoxide 2. In 1959, R. Huttel et al. found that benzyl hydroperoxide 4 is formed by treating benzyl chloride 3 with an excess of hydrogen peroxide (90% aq. solution) in the presence of tin (IV) chloride as a catalyst [96] . The yield of benzyl hydroperoxide 4 was 23% (Scheme 2). Dussault P. et al. developed an approach to the synthesis of allylated peroxides, peroxyketones, and peroxyesters 18 by SnCl4 or TiCl4-mediated reaction of peroxyacetals 17 with electron-rich alkenes, proceeding via peroxycarbenium ion A. (Scheme 7) [100] [101] [102] . Allylation of monoperoxyacetals 19, 20 makes it possible to obtain peroxides 21, 22 in good yield at −78 °C in methylene chloride. The reaction is catalyzed by TiCl4 and SnCl4 (Scheme 8) [100] . The transformation of alkyl peroxides under the action of Lewis acids has been described, where 1,2-dioxanes, 1,2-dioxepanes, and 1,2-dioxocanes are formed as target products [87] . Thus, intramolecular cyclization of peroxyacetals 23, 25, and 27, containing an electron-rich double bond, occurs with the formation of cyclic peroxides 24, 26, and 28, respectively, under action of 1 equiv. of TiCl 4 or SnCl 4 at −78 • C in CH 2 Cl 2 at the N 2 atmosphere (Scheme 9). The size of the peroxide ring depends on the position of the double bond in the starting alkyl peroxide. The interaction of allyltrimethylsilane with α-alkoxyhydroperoxides 29, promoted by SnCl 4 and TiCl 4 , afforded with the formation of substituted 1,2-dioxolanes 30 (Scheme 10) [101] . The reaction mechanism of the formation of 1,2-dioxolane 30 includes the formation of hydroperoxycarbenium ion A peroxyacetal 29 under the action of SnCl 4 or TiCl 4 at the first step. Then hydroperoxycarbenium ion A undergoes nucleophilic attack by allyltrimethylsilane to form cation B, the cyclization of which leads to the 1,2-dioxolane 30 (Scheme 11) [101] . scribed, where 1,2-dioxanes, 1,2-dioxepanes, and 1,2-dioxocanes are formed as target products [87] . Thus, intramolecular cyclization of peroxyacetals 23, 25, and 27, containing an electron-rich double bond, occurs with the formation of cyclic peroxides 24, 26, and 28, respectively, under action of 1 equiv. of TiCl4 or SnCl4 at −78 °C in CH2Cl2 at the N2 atmosphere (Scheme 9). The size of the peroxide ring depends on the position of the double bond in the starting alkyl peroxide. The interaction of allyltrimethylsilane with α-alkoxyhydroperoxides 29, promoted by SnCl4 and TiCl4, afforded with the formation of substituted 1,2-dioxolanes 30 (Scheme 10) [101] . The reaction mechanism of the formation of 1,2-dioxolane 30 includes the formation of hydroperoxycarbenium ion A peroxyacetal 29 under the action of SnCl4 or TiCl4 at the first step. Then hydroperoxycarbenium ion A undergoes nucleophilic attack by allyltrimethylsilane to form cation B, the cyclization of which leads to the 1,2-dioxolane 30 (Scheme 11) [101] . The reaction mechanism of the formation of 1,2-dioxolane 30 includes the formation of hydroperoxycarbenium ion A peroxyacetal 29 under the action of SnCl4 or TiCl4 at the first step. Then hydroperoxycarbenium ion A undergoes nucleophilic attack by allyltrimethylsilane to form cation B, the cyclization of which leads to the 1,2-dioxolane 30 (Scheme 11) [101] . Scheme 11. Probable mechanism of 1,2-dioxolane 30 formation. The above-mentioned approach was used to transform ozonides 31 into 1,2-dioxolanes 32. This reaction proceeds under the action of SnCl4/AllylTMS system in a nitrogen atmosphere at the temperature range from −78 °C to 0 °C (Scheme 12) [103] . In the absence of allyltrimethylsilane, TiCl4 or SnCl4 can catalyze the heterolysis of the O-O-bond in ozonides. This reaction proceeds with the formation of the corresponding lactones and ketones (Scheme 13). The transformation of ozonides 31 into 1,2-dioxolanes Scheme 11. Probable mechanism of 1,2-dioxolane 30 formation. The above-mentioned approach was used to transform ozonides 31 into 1,2-dioxolanes 32. This reaction proceeds under the action of SnCl 4 /AllylTMS system in a nitrogen atmosphere at the temperature range from −78 • C to 0 • C (Scheme 12) [103] . The reaction mechanism of the formation of 1,2-dioxolane 30 includes the formation of hydroperoxycarbenium ion A peroxyacetal 29 under the action of SnCl4 or TiCl4 at the first step. Then hydroperoxycarbenium ion A undergoes nucleophilic attack by allyltrimethylsilane to form cation B, the cyclization of which leads to the 1,2-dioxolane 30 (Scheme 11) [101] . Scheme 11. Probable mechanism of 1,2-dioxolane 30 formation. The above-mentioned approach was used to transform ozonides 31 into 1,2-dioxolanes 32. This reaction proceeds under the action of SnCl4/AllylTMS system in a nitrogen atmosphere at the temperature range from −78 °C to 0 °C (Scheme 12) [103] . In the absence of allyltrimethylsilane, TiCl 4 or SnCl 4 can catalyze the heterolysis of the O-O-bond in ozonides. This reaction proceeds with the formation of the corresponding lactones and ketones (Scheme 13). The transformation of ozonides 31 into 1,2-dioxolanes 32 under the action of SnCl 4 in the presence of allyltrimethylsilane proceeds through Path A and Path B, including the ionization of both C-O and C-OO bonds [104] . The SnCl 4 or TiCl 4 -mediated reaction between peroxyacetals 33 and electron-rich alkenes results in the formation of functionalized 3,5-disubstituted 1,2-dioxolanes 34 through the formation of a peroxycarbenium ion, which is attacked by the nucleophile. (Scheme 14) [105] . The interaction of silylperoxyacetals 35 with alkenes 36 promoted by SnCl 4 leads to in the formation of substituted 1,2-dioxolanes 37. This process proceeds through the formation of the trimethylsilyl peroxycarbenium ion (Scheme 15) [82, 106, 107] . It was found that 1,2-dioxolanes 37a and 37b have a high antimalarial activity against P. falciparum [108] . This approach was used for the synthesis of 1,2-dioxalane (OZ78) 40, which exhibits high activity against Fasciola hepatica (Scheme 16) [109] . The SnCl4 or TiCl4-mediated reaction between peroxyacetals 33 and electron-rich kenes results in the formation of functionalized 3,5-disubstituted 1,2-dioxolanes through the formation of a peroxycarbenium ion, which is attacked by the nucleophi (Scheme 14) [105] . The interaction of silylperoxyacetals 35 with alkenes 36 promoted by SnCl4 leads in the formation of substituted 1,2-dioxolanes 37. This process proceeds through the fo mation of the trimethylsilyl peroxycarbenium ion (Scheme 15) [82, 106, 107] . It was foun that 1,2-dioxolanes 37a and 37b have a high antimalarial activity against P. falciparu [108] . A and Path B, including the ionization of both C-O and C-OO bonds [104] . The SnCl4 or TiCl4-mediated reaction between peroxyacetals 33 and electron-rich a kenes results in the formation of functionalized 3,5-disubstituted 1,2-dioxolanes 3 through the formation of a peroxycarbenium ion, which is attacked by the nucleophil (Scheme 14) [105] . The interaction of silylperoxyacetals 35 with alkenes 36 promoted by SnCl4 leads in the formation of substituted 1,2-dioxolanes 37. This process proceeds through the fo mation of the trimethylsilyl peroxycarbenium ion (Scheme 15) [82, 106, 107] . It was foun that 1,2-dioxolanes 37a and 37b have a high antimalarial activity against P. falciparu [108] . Natural compounds with antitumor activity, such as stereoisomers of plakinic acids 47a,b, were synthesized from peroxide 44 in three steps (Scheme 18). The key 1,2-dioxolane 46 in this sequence was synthesized from α-alkoxydioxolane 44 and O,S-ketene acetal 45 promoted by TiCl4 in 82% yield (Scheme 18). Both isomers of acid 47a,b were isolated in individual form [111] . Also it was found that plakinic acids 47 inhibit the growth of the fungi Saccharomyces cerevisiae and Penicillium atrounenetum [39] . It was found that the type of peroxidation product of allylic alcohols containing a lactam ring 48 depends on the amount of Lewis acid. Thus, peroxidation of alcohol 48 with the use of 0.9 eq. of SnCl4 leads to the formation of both mono-and diperoxides 49 and 50. Increasing the amount of acid to 2.5 eq. with respect to 48 leads to the formation of epoxyalkyl peroxide 51 (Scheme 19) [112] . Anchimeric assistance of the hydroxyl group facilitates the addition of tert-butyl hydroperoxide to the double bond. Under the action of SnCl4, through the formation of a carbocation, the nucleophilic substitution of the hydroxyl group for tert-butyl peroxide occurs. It was found that the type of peroxidation product of allylic alcohols containing a lactam ring 48 depends on the amount of Lewis acid. Thus, peroxidation of alcohol 48 with the use of 0.9 eq. of SnCl 4 leads to the formation of both mono-and diperoxides 49 and 50. Increasing the amount of acid to 2.5 eq. with respect to 48 leads to the formation of epoxyalkyl peroxide 51 (Scheme 19) [112] . Anchimeric assistance of the hydroxyl group facilitates the addition of tert-butyl hydroperoxide to the double bond. Under the action of SnCl 4 , through the formation of a carbocation, the nucleophilic substitution of the hydroxyl group for tert-butyl peroxide occurs. Catalysis of the peroxidation reaction of acetylacetone 52 by strong protic acids (H 2 SO 4 , HClO 4 , HCl) leads to a complex mixture of cyclic and acyclic peroxides. However, with the use of SnCl 2 ·2H 2 O and AlCl 3 ·6H 2 O as a catalyst, the peroxidation of acetylacetone 52 proceeds selectively with the formation of dihydroperoxo-1,2-dioxolane 53 (Scheme 20) [113, 114] . The reaction was carried out at a room temperature with 5-25 molar excess of 30% aq. solution of H 2 O 2 and 10-20 mol% LA with respect to 52. The SnCl 2 ·2H 2 O/H 2 O 2 system was used in the peroxidation of 2,5-heptadione 54. In this case, the reaction proceeds with the formation of hydroxyhydroperoxy 1,2-dioxane 55, but in a low yield of target compound of 15% (Scheme 21) [115] . The reaction was carried out at a room temperature with 5-fold molar excess of 50% aq. solution of H 2 O 2 and 20 mol. % SnCl 2 ·2H 2 O with respect to 54. The reaction of acetals 56 with 1,1 -dihydroperoxydi (cycloalkyl) peroxides 57 catalyzed by SnCl 4 afforded with the formation of 1,2,4,5,7,8-hexaoxananes 58. This approach makes it possible to solve the problem of the synthesis of hexaoxonanes from cycloalkanones with ring sizes C6-C8 and C12 (Scheme 22) [88] . Catalysis of the peroxidation reaction of acetylacetone 52 by strong protic acids (H2SO4, HClO4, HCl) leads to a complex mixture of cyclic and acyclic peroxides. However, with the use of SnCl2·2H2O and AlCl3·6H2O as a catalyst, the peroxidation of acetylacetone 52 proceeds selectively with the formation of dihydroperoxo-1,2-dioxolane 53 (Scheme 20) [113, 114] . The reaction was carried out at a room temperature with 5-25 molar excess of 30% aq. solution of H2O2 and 10-20 mol% LA with respect to 52. The SnCl2·2H2O/H2O2 system was used in the peroxidation of 2,5-heptadione 54. In this case, the reaction proceeds with the formation of hydroxyhydroperoxy 1,2-dioxane 55, but in a low yield of target compound of 15% (Scheme 21) [115] . The reaction was carried out at a room temperature with 5-fold molar excess of 50% aq. solution of H2O2 and 20 mol. % SnCl2·2H2O with respect to 54. Catalysis of the peroxidation reaction of acetylacetone 52 by strong protic acids (H2SO4, HClO4, HCl) leads to a complex mixture of cyclic and acyclic peroxides. However, with the use of SnCl2·2H2O and AlCl3·6H2O as a catalyst, the peroxidation of acetylacetone 52 proceeds selectively with the formation of dihydroperoxo-1,2-dioxolane 53 (Scheme 20) [113, 114] . The reaction was carried out at a room temperature with 5-25 molar excess of 30% aq. solution of H2O2 and 10-20 mol% LA with respect to 52. The SnCl2·2H2O/H2O2 system was used in the peroxidation of 2,5-heptadione 54. In this case, the reaction proceeds with the formation of hydroxyhydroperoxy 1,2-dioxane 55, but in a low yield of target compound of 15% (Scheme 21) [115] . The reaction was carried out at a room temperature with 5-fold molar excess of 50% aq. solution of H2O2 and 20 mol. % SnCl2·2H2O with respect to 54. The reaction of acetals 56 with 1,1′-dihydroperoxydi (cycloalkyl) peroxides 57 catalyzed by SnCl4 afforded with the formation of 1,2,4,5,7,8-hexaoxananes 58. This approach makes it possible to solve the problem of the synthesis of hexaoxonanes from cycloalkanones with ring sizes C6-C8 and C12 (Scheme 22) [88] . The reaction of acetals 56 with 1,1′-dihydroperoxydi (cycloalkyl) peroxides 57 catalyzed by SnCl4 afforded with the formation of 1,2,4,5,7,8-hexaoxananes 58. This approach makes it possible to solve the problem of the synthesis of hexaoxonanes from cycloalkanones with ring sizes C6-C8 and C12 (Scheme 22) [88] . The proposed mechanism of ketone peroxidation by the H2O2/MeReO3 system is based on the coordination of hydrogen peroxide with rhenium, which acts as a Lewis acid with the formation of peroxocomplex 61(Scheme 23) [116] [117] [118] . The resulting peroxocomplex 61 interacts with a carbonyl compound with the transfer of a peroxo group. Furthermore, MeReO3 can react with a carbonyl group, as a Lewis acid to activate the carbonyl carbon atom. The addition of HBF4 to the 30% aq. H2O2/MeReO3 system leads to the formation of symmetric 1,2,4,5-tetraoxanes 63 from cyclic ketones 62, as well as 3,3,6,6-tetraalkyl-1,2,4,5-tetraoxanes 63 from unsymmetrical ketones 62, respectively (Scheme 24) [119] . 1,2,4,5-Tetraoxanes 63a-e exhibit antimalarial activity against the chloroquine-resistant strain of P. falciparum. The proposed mechanism of ketone peroxidation by the H 2 O 2 /MeReO 3 system is based on the coordination of hydrogen peroxide with rhenium, which acts as a Lewis acid with the formation of peroxocomplex 61 (Scheme 23) [116] [117] [118] . The resulting peroxocomplex 61 interacts with a carbonyl compound with the transfer of a peroxo group. Furthermore, MeReO 3 can react with a carbonyl group, as a Lewis acid to activate the carbonyl carbon atom. Scheme 21. Synthesis of hydroxyhydroperoxy 1,2-dioxane 55 from 2,5-heptadione 54. The reaction of acetals 56 with 1,1′-dihydroperoxydi (cycloalkyl) peroxides 57 catalyzed by SnCl4 afforded with the formation of 1,2,4,5,7,8-hexaoxananes 58. This approach makes it possible to solve the problem of the synthesis of hexaoxonanes from cycloalkanones with ring sizes C6-C8 and C12 (Scheme 22) [88] . The proposed mechanism of ketone peroxidation by the H2O2/MeReO3 system is based on the coordination of hydrogen peroxide with rhenium, which acts as a Lewis acid with the formation of peroxocomplex 61(Scheme 23) [116] [117] [118] . The resulting peroxocomplex 61 interacts with a carbonyl compound with the transfer of a peroxo group. Furthermore, MeReO3 can react with a carbonyl group, as a Lewis acid to activate the carbonyl carbon atom. The addition of HBF4 to the 30% aq. H2O2/MeReO3 system leads to the formation of symmetric 1,2,4,5-tetraoxanes 63 from cyclic ketones 62, as well as 3,3,6,6-tetraalkyl-1,2,4,5-tetraoxanes 63 from unsymmetrical ketones 62, respectively (Scheme 24) [119] . 1,2,4,5-Tetraoxanes 63a-e exhibit antimalarial activity against the chloroquine-resistant strain of P. falciparum. The addition of HBF 4 to the 30% aq. H 2 O 2 /MeReO 3 system leads to the formation of symmetric 1,2,4,5-tetraoxanes 63 from cyclic ketones 62, as well as 3,3,6,6-tetraalkyl-1,2,4,5tetraoxanes 63 from unsymmetrical ketones 62, respectively (Scheme 24) [119] . 1,2,4,5-Tetraoxanes 63a-e exhibit antimalarial activity against the chloroquine-resistant strain of P. falciparum. The combination 30% aq. H2O2/MeReO3/HBF4 in TFE is an effective system for the synthesis of both symmetric 69 and non-symmetric tetraoxanes 66 or 68 from aldehydes 64 in good yields (Scheme 25) [120] [121] [122] . It was found that such tetraoxanes exhibit antimalarial activity in vitro. The combination 30% aq. H 2 O 2 /MeReO 3 /HBF 4 in TFE is an effective system for the synthesis of both symmetric 69 and non-symmetric tetraoxanes 66 or 68 from aldehy- Non-symmetric tetraoxanes 72 were synthesized from 4-methyl cyclohexanone 70 and ketone or aldehyde 71 under the action of H2O2 in the presence of 1 eq. of HBF4 and 0.1 mol% of MeReO3 with respect to the starting ketone in TFE medium. (Scheme 26) [122] . The interaction of sulfonylpiperide-4ones 73 with ketones 74, 76 promoted by H2O2/MeReO3/HBF4 in HFIP leads to the formation of non-symmetric 1,2,4,5-tetraoxanes 75 and 77, which exhibit high antimalarial activity (Scheme 27) [123] . Non-symmetric tetraoxanes 72 were synthesized from 4-methyl cyclohexanone 70 and ketone or aldehyde 71 under the action of H2O2 in the presence of 1 eq. of HBF4 and 0.1 mol% of MeReO3 with respect to the starting ketone in TFE medium. (Scheme 26) [122] . In The interaction of Donor-Acceptor cyclopropane 88 with t BuOOH and N-halosuccinimides 89, which acts as a source of halogen, provides haloperoxides 90 in moderate to good yields (Scheme 31) [92] . It is noteworthy that the interaction of cyclopropanes 91 containing one acceptor substituent with tert-butyl hydroperoxide under the action of 0.5 eq. Sc(OTf) 3 leads to bis-tert-butyl peroxides 92 in 56-72% yields (Scheme 32) [92] . The interaction of Donor-Acceptor cyclopropane 88 with t BuOOH and N-halosuccinimides 89, which acts as a source of halogen, provides haloperoxides 90 in moderate to good yields (Scheme 31) [92] . The interaction of Donor-Acceptor cyclopropane 88 with t BuOOH and N-halosuccinimides 89, which acts as a source of halogen, provides haloperoxides 90 in moderate to good yields (Scheme 31) [92] . It is noteworthy that the interaction of cyclopropanes 91 containing one acceptor substituent with tert-butyl hydroperoxide under the action of 0.5 eq. Sc(OTf)3 leads to bis-tertbutyl peroxides 92 in 56-72% yields (Scheme 32) [92] . The use of the H2O2 or TBHP/Sc(OTf)3 system for ring opening of donor-acceptor aziridines 92 leads to α-sulfanilamido peroxides 93 and 94 in good yield (Scheme 33) [126] . The reaction can be scaled up to the grams in 70% yield. The use of the H 2 O 2 or TBHP/Sc(OTf) 3 system for ring opening of donor-acceptor aziridines 92 leads to α-sulfanilamido peroxides 93 and 94 in good yield (Scheme 33) [126] . The reaction can be scaled up to the grams in 70% yield. It is noteworthy that the interaction of cyclopropanes 91 containing one acceptor substituent with tert-butyl hydroperoxide under the action of 0.5 eq. Sc(OTf)3 leads to bis-tertbutyl peroxides 92 in 56-72% yields (Scheme 32) [92] . The use of the H2O2 or TBHP/Sc(OTf)3 system for ring opening of donor-acceptor aziridines 92 leads to α-sulfanilamido peroxides 93 and 94 in good yield (Scheme 33) [126] . The reaction can be scaled up to the grams in 70% yield. Hydroperoxyoxetane 98 rearranged into endoperoxide 99 in 12% yield and exoperoxide 100 in 33% yield under the action of Yb(OTf) 3 in methylene chloride (Scheme 35) [74] . The use of catalytic amounts of Sc(OTf) 3 or InCl 3 in the reaction of endoperoxyacetals 101 with allyltrimethylsilane (AllylTMS) and its derivatives (Nu-TMS) makes it possible to obtain 3,5-disubstituted-1,2-dioxolanes 102 and 103 by the Sakurai reaction. Sc(OTf) 3 or InCl 3 allow the reaction to be carried out under milder conditions than when using SnCl 4 and TiCl 4 (Scheme 36) [128, 129] . The use of catalytic amounts of Sc(OTf)3 or InCl3 in the reaction of endoperoxyacetals 101 with allyltrimethylsilane (AllylTMS) and its derivatives (Nu-TMS) makes it possible to obtain 3,5-disubstituted-1,2-dioxolanes 102 and 103 by the Sakurai reaction. Sc(OTf)3 or InCl3 allow the reaction to be carried out under milder conditions than when using SnCl4 and TiCl4 (Scheme 36) [128, 129] . The use of catalytic amounts of Sc(OTf)3 or InCl3 in the reaction of endoperoxyacetals 101 with allyltrimethylsilane (AllylTMS) and its derivatives (Nu-TMS) makes it possible to obtain 3,5-disubstituted-1,2-dioxolanes 102 and 103 by the Sakurai reaction. Sc(OTf)3 or InCl3 allow the reaction to be carried out under milder conditions than when using SnCl4 and TiCl4 (Scheme 36) [128, 129] . In a process known as peroxymercuration, alkyl peroxides D, E can be prepared from alkenes A and alkyl hydroperoxide B in the presence of a suitable mercury (II) salt (Scheme 38). In this case, mercury salts act as a mild electrophilic reagent. The interaction of mercury (II) salt with an alkene leads to cationic species, which reacts with alkyl hydroperoxide to form mercurylalkyl peroxides C. The obtained mercurylalkyl peroxides C can be demercurated using sodium borohydride or by bromonolysis. Both peroxymercuration and demercuration occur rapidly under mild conditions. Cyclic peroxides such as spiro 1,2,4-trioxepanes 106 were obtained from hydroperoxides 104 and ketones 105 by using Indium (III) triflate as a catalyst (Scheme 37) [130] . In a process known as peroxymercuration, alkyl peroxides D, E can be prepared from alkenes A and alkyl hydroperoxide B in the presence of a suitable mercury (II) salt (Scheme 38). In this case, mercury salts act as a mild electrophilic reagent. The interaction of mercury (II) salt with an alkene leads to cationic species, which reacts with alkyl hydroperoxide to form mercurylalkyl peroxides C. The obtained mercurylalkyl peroxides C can be demercurated using sodium borohydride or by bromonolysis. Both peroxymercuration and demercuration occur rapidly under mild conditions. Bloodworth A.J. demonstrated a two-stage approach to halogeno-alkyl peroxides 108, 109 (Scheme 39) [131] . At the first stage, peroxymercuration of such unsaturated ketones 107 was carried out with the use of t BuOOH/Hg(OAc)2 system then demercuration of peroxymercurated product afforded with the formation of target peroxides 108, 109 in 32-84% and 45-79% yields, respectively. In a process known as peroxymercuration, alkyl peroxides D, E can be prepared from alkenes A and alkyl hydroperoxide B in the presence of a suitable mercury (II) salt (Scheme 38). In this case, mercury salts act as a mild electrophilic reagent. The interaction of mercury (II) salt with an alkene leads to cationic species, which reacts with alkyl hydroperoxide to form mercurylalkyl peroxides C. The obtained mercurylalkyl peroxides C can be demercurated using sodium borohydride or by bromonolysis. Both peroxymercuration and demercuration occur rapidly under mild conditions. Scheme 38. Synthesis of acyclic peroxides D and E. Bloodworth A.J. demonstrated a two-stage approach to halogeno-alkyl peroxides 108, 109 (Scheme 39) [131] . At the first stage, peroxymercuration of such unsaturated ketones 107 was carried out with the use of t BuOOH/Hg(OAc)2 system then demercuration of peroxymercurated product afforded with the formation of target peroxides 108, 109 in 32-84% and 45-79% yields, respectively. Bloodworth A.J. demonstrated a two-stage approach to halogeno-alkyl peroxides 108, 109 (Scheme 39) [131] . At the first stage, peroxymercuration of such unsaturated ketones 107 was carried out with the use of t BuOOH/Hg(OAc) 2 system then demercuration of peroxymercurated product afforded with the formation of target peroxides 108, 109 in 32-84% and 45-79% yields, respectively. n = 2, R 1 R 2 = (CH 2 ) 5 ; Yield, 10% n = 2, R 1 R 2 = Ad; Yield, 32% Scheme 37. Synthesis of 1,2,4-trioxepanes 106. In a process known as peroxymercuration, alkyl peroxides D, E can be prepared from alkenes A and alkyl hydroperoxide B in the presence of a suitable mercury (II) salt (Scheme 38). In this case, mercury salts act as a mild electrophilic reagent. The interaction of mercury (II) salt with an alkene leads to cationic species, which reacts with alkyl hydroperoxide to form mercurylalkyl peroxides C. The obtained mercurylalkyl peroxides C can be demercurated using sodium borohydride or by bromonolysis. Both peroxymercuration and demercuration occur rapidly under mild conditions. Bloodworth A.J. demonstrated a two-stage approach to halogeno-alkyl peroxides 108, 109 (Scheme 39) [131] . At the first stage, peroxymercuration of such unsaturated ketones 107 was carried out with the use of t BuOOH/Hg(OAc)2 system then demercuration of peroxymercurated product afforded with the formation of target peroxides 108, 109 in 32-84% and 45-79% yields, respectively. Phenyl cyclopropane 110 undergoes ring opening under the action of the t BuOOH/Hg(CF3COO)2 system with the formation of mercurylalkyl peroxide 111 in a 47% yield. Further reduction 111 leads to alkyl peroxide 112 in a 19% yield [132] . yield. Further reduction 111 leads to alkyl peroxide 112 in a 19% yield [132] . T system was applied for the synthesis of peroxide 115 from styrene 113 (Scheme 4 Adam W. et al. presented a method for the regioselective synthesis of bicyclic peroxide 120 by the peroxymercuration of non-conjugated cyclic dienes 119 (Scheme 42) [134] . Organo-mercury trifluoroacetates were separated by dissolving their mixture in benzene. The peroxide 120 did not dissolve in benzene and precipitated as white crystals. Reductive demercuration of 120 proceeded under mild conditions with the formation of bridged 1,2-dioxepane 124. Bromination of peroxide 120 followed by demercuration led to dibromocycloperoxide 123. The peroxymercuration and demercuration of 1,4-cyclooctadiene 125 proceeded in a similar way with the formation of peroxides 126 and 127 (Scheme 43). Peroxides 126 and 127 were obtained in 38% and 28% yield respectively [135] . The peroxymercuration and demercuration of 1,4-cyclooctadiene 125 proceeded in a similar way with the formation of peroxides 126 and 127 (Scheme 43). Peroxides 126 and 127 were obtained in 38% and 28% yield respectively [135] . The peroxymercuration and demercuration of 1,4-cyclooctadiene 125 proceeded in a similar way with the formation of peroxides 126 and 127 (Scheme 43). Peroxides 126 and 127 were obtained in 38% and 28% yield respectively [135] . The peroxymercuration and demercuration of 1,4-cyclooctadiene 125 proceeded in a similar way with the formation of peroxides 126 and 127 (Scheme 43). Peroxides 126 and 127 were obtained in 38% and 28% yield respectively [135] . Direct demercuration of peroxides 134 is not possible because the hydroperoxide group is reduced under the action of sodium borohydride. However, the subsequent protection of hydroperoxy group by 2-methoxypropene, borohydride reduction, and deprotection of peroxy group led to peroxides 135 in 30-54% yield (Scheme 46) [138] . Hydroperoxycyclopropanes 136 under the action of Hg(OAc)2 in the presence of perchloric acid were transformed into 1,2-dioxolanes 137, the bromodemercuration of which led to 1,2-dioxolanes 138 (Scheme 47) [139] . Cyclic peroxides were isolated by column chromatography on SiO2 at 0 °C. The target peroxides 138 were obtained in 52-60% yield. The first example of the synthesis of diastereomeric saturated analogs of plakinic acids A, C and D 142 was described in 1996 by Bloodworth A. J. and colleagues [140] . Peroxides 142 were obtained in four stages from ketones 139. At one stage of this synthetic route, the peroxymercuration of esters 140 was used with the formation of 1,2-dioxolanes Direct demercuration of peroxides 134 is not possible because the hydroperoxide group is reduced under the action of sodium borohydride. However, the subsequent protection of hydroperoxy group by 2-methoxypropene, borohydride reduction, and deprotection of peroxy group led to peroxides 135 in 30-54% yield (Scheme 46) [138] . Direct demercuration of peroxides 134 is not possible because the hydroperoxide group is reduced under the action of sodium borohydride. However, the subsequent protection of hydroperoxy group by 2-methoxypropene, borohydride reduction, and deprotection of peroxy group led to peroxides 135 in 30-54% yield (Scheme 46) [138] . Hydroperoxycyclopropanes 136 under the action of Hg(OAc)2 in the presence of perchloric acid were transformed into 1,2-dioxolanes 137, the bromodemercuration of which led to 1,2-dioxolanes 138 (Scheme 47) [139] . Cyclic peroxides were isolated by column chromatography on SiO2 at 0 °C. The target peroxides 138 were obtained in 52-60% yield. The first example of the synthesis of diastereomeric saturated analogs of plakinic acids A, C and D 142 was described in 1996 by Bloodworth A. J. and colleagues [140] . Peroxides 142 were obtained in four stages from ketones 139. At one stage of this synthetic route, the peroxymercuration of esters 140 was used with the formation of 1,2-dioxolanes Hydroperoxycyclopropanes 136 under the action of Hg(OAc) 2 in the presence of perchloric acid were transformed into 1,2-dioxolanes 137, the bromodemercuration of which led to 1,2-dioxolanes 138 (Scheme 47) [139] . Cyclic peroxides were isolated by column chromatography on SiO 2 at 0 • C. The target peroxides 138 were obtained in 52-60% yield. Hydroperoxymercuration of alkenes 130 with the use of aq. H2O2 proceeds with the formation of hydroperoxide 131 and alcohol 132. The resulting peroxides 131 were obtained in yield up to 86% (Scheme 45) [137, 138] . Direct demercuration of peroxides 134 is not possible because the hydroperoxide group is reduced under the action of sodium borohydride. However, the subsequent protection of hydroperoxy group by 2-methoxypropene, borohydride reduction, and deprotection of peroxy group led to peroxides 135 in 30-54% yield (Scheme 46) [138] . Hydroperoxycyclopropanes 136 under the action of Hg(OAc)2 in the presence of perchloric acid were transformed into 1,2-dioxolanes 137, the bromodemercuration of which led to 1,2-dioxolanes 138 (Scheme 47) [139] . Cyclic peroxides were isolated by column chromatography on SiO2 at 0 °C. The target peroxides 138 were obtained in 52-60% yield. The first example of the synthesis of diastereomeric saturated analogs of plakinic acids A, C and D 142 was described in 1996 by Bloodworth A. J. and colleagues [140] . Peroxides 142 were obtained in four stages from ketones 139. At one stage of this synthetic route, the peroxymercuration of esters 140 was used with the formation of 1,2-dioxolanes Scheme 47. Synthesis of 1,2-dioxolane 138. The first example of the synthesis of diastereomeric saturated analogs of plakinic acids A, C and D 142 was described in 1996 by Bloodworth A. J. and colleagues [140] . Peroxides 142 were obtained in four stages from ketones 139. At one stage of this synthetic route, the peroxymercuration of esters 140 was used with the formation of 1,2-dioxolanes 141. Saponification of which led to 1,2-dioxolanes 142 with a free carboxyl group (Scheme 48). Zhang and Li reported the synthesis of β-hydroperoxy alcohols 144 by the reaction of epoxides 143 with H2O2, catalyzed by silica-supported antimony trichloride (SbCl3/SiO2) (Scheme 49) [141] . Interestingly, the authors demonstrated that SbCl3/SiO2 is more active than unsupported-SbCl3. Under the best conditions, a range of β-hydroxy hydroperoxides 144 was obtained in 72-86% isolated yields. Zhang and Li reported the synthesis of β-hydroperoxy alcohols 144 by the reaction of epoxides 143 with H 2 O 2 , catalyzed by silica-supported antimony trichloride (SbCl 3 /SiO 2 ) (Scheme 49) [141] . Interestingly, the authors demonstrated that SbCl 3 /SiO 2 is more active than unsupported-SbCl 3 . Under the best conditions, a range of β-hydroxy hydroperoxides 144 was obtained in 72-86% isolated yields. Saponification of which led to 1,2-dioxolanes 142 with a free carboxyl group (Scheme 48). Zhang and Li reported the synthesis of β-hydroperoxy alcohols 144 by the reaction of epoxides 143 with H2O2, catalyzed by silica-supported antimony trichloride (SbCl3/SiO2) (Scheme 49) [141] . Interestingly, the authors demonstrated that SbCl3/SiO2 is more active than unsupported-SbCl3. Under the best conditions, a range of β-hydroxy hydroperoxides 144 was obtained in 72-86% isolated yields. Lewis acids such as SrCl3·6H2O [142] , cerium ammonium nitrate (CAN) [143] , Bi(OTf)3 [144] , and AlCl3·6H2O [114] are effective catalysts for the synthesis of bishydroperoxides 149-152 from cyclic and acyclic ketones and aldehydes 148. Peroxidation proceeds under mild conditions at room temperature with the formation of target peroxides in a good yield. All Lewis acids demonstrated approximately equal efficiency in the peroxidation reaction. The main advantage of these methods is the use of Lewis acids in catalytic amounts and an inexpensive 30% aqueous H2O2 (Scheme 51 Lewis acids such as SrCl3·6H2O [142] , cerium ammonium nitrate (CAN) [143] , Bi(OTf)3 [144] , and AlCl3·6H2O [114] are effective catalysts for the synthesis of bishydroperoxides 149-152 from cyclic and acyclic ketones and aldehydes 148. Peroxidation proceeds under mild conditions at room temperature with the formation of target peroxides in a good yield. All Lewis acids demonstrated approximately equal efficiency in the peroxidation reaction. The main advantage of these methods is the use of Lewis acids in catalytic amounts and an inexpensive 30% aqueous H2O2 (Scheme 51 Also, bismuth (III) triflate is a good catalyst for the synthesis of 1,2,4,5-tetraoxanes 155. In this case, the target peroxides 152 were obtained in a yield up to 94%. Synthetic 1,2,4,5-tetraoxane 155a exhibits high activity against helminths Fasciola hepatica and in rats in vivo (Scheme 52) [144, 145] . Also, bismuth (III) triflate is a good catalyst for the synthesis of 1,2,4,5-tetraoxanes 155. In this case, the target peroxides 152 were obtained in a yield up to 94%. Synthetic 1,2,4,5-tetraoxane 155a exhibits high activity against helminths Fasciola hepatica and in rats in vivo (Scheme 52) [144, 145] . The palladium-catalyzed cyclization of unsaturated hydroperoxides 158 afforded with the formation of 1,2-dioxanes 159 (Scheme 54) [147] . The reaction was carried out in toluene, 1,4-dioxane, or 1,2-dichloroethane at 80 °C for 3h. To oxidize Pd(0), which is formed in the catalytic cycle, p-benzoquinone (BQ) or silver carbonate were used. The interaction of 1,2,4-trioxolanes (ozonides) 156 with Lewis acid SbCl 5 in methylene chloride led to 1,2,4,5-tetraoxanes 157 (Scheme 53) [146] . Also, bismuth (III) triflate is a good catalyst for the synthesis of 1,2,4,5-tetraoxanes 155. In this case, the target peroxides 152 were obtained in a yield up to 94%. Synthetic 1,2,4,5-tetraoxane 155a exhibits high activity against helminths Fasciola hepatica and in rats in vivo (Scheme 52) [144, 145] . The palladium-catalyzed cyclization of unsaturated hydroperoxides 158 afforded with the formation of 1,2-dioxanes 159 (Scheme 54) [147] . The reaction was carried out in toluene, 1,4-dioxane, or 1,2-dichloroethane at 80 °C for 3h. To oxidize Pd(0), which is formed in the catalytic cycle, p-benzoquinone (BQ) or silver carbonate were used. The palladium-catalyzed cyclization of unsaturated hydroperoxides 158 afforded with the formation of 1,2-dioxanes 159 (Scheme 54) [147] . The reaction was carried out in toluene, 1,4-dioxane, or 1,2-dichloroethane at 80 • C for 3h. To oxidize Pd(0), which is formed in the catalytic cycle, p-benzoquinone (BQ) or silver carbonate were used. Also, bismuth (III) triflate is a good catalyst for the synthesis of 1,2,4,5-tetraoxanes 155. In this case, the target peroxides 152 were obtained in a yield up to 94%. Synthetic 1,2,4,5-tetraoxane 155a exhibits high activity against helminths Fasciola hepatica and in rats in vivo (Scheme 52) [144, 145] . The palladium-catalyzed cyclization of unsaturated hydroperoxides 158 afforded with the formation of 1,2-dioxanes 159 (Scheme 54) [147] . The reaction was carried out in toluene, 1,4-dioxane, or 1,2-dichloroethane at 80 °C for 3h. To oxidize Pd(0), which is formed in the catalytic cycle, p-benzoquinone (BQ) or silver carbonate were used. Such a Lewis acid as Cu(OTf)2 turned out to be the most effective catalyst for the synthesis of peroxides 162 by the ring opening reaction of activated aziridines 160 under the action of various hydroperoxides 161. It was found that electron-neutral or halogenated substrates 160 provide better results in comparison with substrates containing electron-withdrawing substituents in an aromatic ring (Scheme 56) [126] . Such a Lewis acid as Cu(OTf) 2 turned out to be the most effective catalyst for the synthesis of peroxides 162 by the ring opening reaction of activated aziridines 160 under the action of various hydroperoxides 161. It was found that electron-neutral or halogenated substrates 160 provide better results in comparison with substrates containing electronwithdrawing substituents in an aromatic ring (Scheme 56) [126] . There is great interest in Lewis acids based on non-metals. Their use as a catalyst or reagent made it possible to discover new classes of peroxides of various structures. This section contains data on the synthesis of 1-hydroperoxy-1′-alkoxyperoxides, β-hydroperoxy-β-peroxylactones, 1,2-dioxanes, 1,2,4-trioxepanes, 1,2,4-trioxocanes, 1,2,4-trioxonanes Scheme 56. Synthesis of peroxides 162 from substituted aziridines 160. There is great interest in Lewis acids based on non-metals. Their use as a catalyst or reagent made it possible to discover new classes of peroxides of various structures. This section contains data on the synthesis of 1-hydroperoxy-1 -alkoxyperoxides, β-hydroperoxyβ-peroxylactones, 1,2-dioxanes, 1,2,4-trioxepanes, 1,2,4-trioxocanes, 1,2,4-trioxonanes and 1,2,4,5,7,8-hexaoxananes. The first mentions of the formation of peroxides under the action of boron trifluoride goes back to the 1950s. A US patent 2,630,456 [148] from 1953 describes a selective method for producing tert-butyl hydroperoxide 164 from the corresponding alcohol 163 [149] . The reaction was carried out at room temperature using an equimolar amount of a 50% aqueous solution of hydrogen peroxide with 0.3 eq. of boron trifluoride etherate (Scheme 57). Since BF 3 can form BF 3 ·H 2 O complex [150] [151] [152] [153] [154] [155] , this makes it possible to use BF 3 ·Et 2 O in the presence of water. 69% 55% Scheme 56. Synthesis of peroxides 162 from substituted aziridines 160. There is great interest in Lewis acids based on non-metals. Their use as a catalyst o reagent made it possible to discover new classes of peroxides of various structures. Thi section contains data on the synthesis of 1-hydroperoxy-1′-alkoxyperoxides, β-hydroper oxy-β-peroxylactones, 1,2-dioxanes, 1,2,4-trioxepanes, 1,2,4-trioxocanes, 1,2,4-trioxonane and 1,2,4,5,7,8-hexaoxananes. The first mentions of the formation of peroxides under the action of boron trifluoride goes back to the 1950s. A US patent 2,630,456 [148] from 1953 describes a selective method for producing tert-butyl hydroperoxide 164 from the corresponding alcohol 163 [149] . The reaction was carried out at room temperature using an equimolar amount of a 50% aque ous solution of hydrogen peroxide with 0.3 eq. of boron trifluoride etherate (Scheme 57) Since BF3 can form BF3·H2O complex [150] [151] [152] [153] [154] [155] , this makes it possible to use BF3·Et2O in the presence of water. The reaction of vinyl esters 167 and hydroperoxides 168 in the presence of gaseous boron trifluoride leads to the formation of monoperoxyketals 169. The reaction was carried out in benzene or hexane at temperatures from 0 to 30 °C (Scheme 59) [157] . The reaction proceeds within 5-10 min with a yield of 80-96%. This method is the first way to obtain monoperoxyacetals in high yields. The reaction of vinyl esters 167 and hydroperoxides 168 in the presence of gaseous boron trifluoride leads to the formation of monoperoxyketals 169. The reaction was carried out in benzene or hexane at temperatures from 0 to 30 • C (Scheme 59) [157] . The reaction proceeds within 5-10 min with a yield of 80-96%. This method is the first way to obtain monoperoxyacetals in high yields. The reaction of vinyl esters 167 and hydroperoxides 168 in the presence of gaseous boron trifluoride leads to the formation of monoperoxyketals 169. The reaction was carried out in benzene or hexane at temperatures from 0 to 30 °C (Scheme 59) [157] . The reaction proceeds within 5-10 min with a yield of 80-96%. This method is the first way to obtain monoperoxyacetals in high yields. The synthesis of alkyl peroxides 171 was carried out by the reaction of tertiary alkyltrichloroacetimides 170 with tert-butyl hydroperoxide in the presence of boron trifluoride etherate (Scheme 60) [158] . A wide range of bishydroperoxides 175 was obtained from acetals 173, enol ethers 174 and hydrogen peroxide in the presence of boron trifluoride etherate (Scheme 61) [159, 160] . The developed method allows one to obtain peroxides of various structures. The advantages of these reactions are the rapidity and ease of its implementation, and among the disadvantages can be noted the formation of by-products, as well as the impossibility of synthesizing bishydroperoxides from acetals or enol ethers obtained from aryl-substituted ketones. of these reactions are the rapidity and ease of its implementation, and among the disadvantages can be noted the formation of by-products, as well as the impossibility of synthesizing bishydroperoxides from acetals or enol ethers obtained from aryl-substituted ketones. 32% 56% Scheme 60. Synthesis of alkyl peroxides 171. A wide range of bishydroperoxides 175 was obtained from acetals 173, enol ethers 174 and hydrogen peroxide in the presence of boron trifluoride etherate (Scheme 61) [159, 160] . The developed method allows one to obtain peroxides of various structures. The advantages of these reactions are the rapidity and ease of its implementation, and among the disadvantages can be noted the formation of by-products, as well as the impossibility of synthesizing bishydroperoxides from acetals or enol ethers obtained from aryl-substituted ketones. The possibility to obtain geminal bis(tert-butyl)peroxides 178 of both cyclic and acyclic structures with a yield of 13% to 89%, respectively, was described from acetals 176 and enol ethers 177 (Scheme 63) [161] . The reaction of the enol esters 177 with tert-butyl hydroperoxide, catalyzed by boron trifluoride etherate, is a general approach for the preparation of geminal bishydroperoxides. 1,2-Dioxane 180 was obtained by the reaction of the corresponding acetal 179 with urea hydrogen peroxide, catalyzed by boron trifluoride etherate (Scheme 64) [162] . Under these conditions, only one of the two methoxyl groups is exchanged for the hydroperoxide one, and the intermediate hydroperoxyketal undergoes intramolecular cyclization (according to Michael) due to the attack of the hydroperoxide group on the double bond activated by the nitro group with the formation of 1,2-dioxane in 51% yield. The possibility to obtain geminal bis(tert-butyl)peroxides 178 of both cyclic and acyclic structures with a yield of 13% to 89%, respectively, was described from acetals 176 and enol ethers 177 (Scheme 63) [161] . The reaction of the enol esters 177 with tert-butyl hydroperoxide, catalyzed by boron trifluoride etherate, is a general approach for the preparation of geminal bishydroperoxides. The possibility to obtain geminal bis(tert-butyl)peroxides 178 of both cyclic and acyclic structures with a yield of 13% to 89%, respectively, was described from acetals 176 and enol ethers 177 (Scheme 63) [161] . The reaction of the enol esters 177 with tert-butyl hydroperoxide, catalyzed by boron trifluoride etherate, is a general approach for the preparation of geminal bishydroperoxides. 1,2-Dioxane 180 was obtained by the reaction of the corresponding acetal 179 with urea hydrogen peroxide, catalyzed by boron trifluoride etherate (Scheme 64) [162] . Under these conditions, only one of the two methoxyl groups is exchanged for the hydroperoxide one, and the intermediate hydroperoxyketal undergoes intramolecular cyclization (according to Michael) due to the attack of the hydroperoxide group on the double bond activated by the nitro group with the formation of 1,2-dioxane in 51% yield. 1,2-Dioxane 180 was obtained by the reaction of the corresponding acetal 179 with urea hydrogen peroxide, catalyzed by boron trifluoride etherate (Scheme 64) [162] . Under these conditions, only one of the two methoxyl groups is exchanged for the hydroperoxide one, and the intermediate hydroperoxyketal undergoes intramolecular cyclization (according to Michael) due to the attack of the hydroperoxide group on the double bond activated by the nitro group with the formation of 1,2-dioxane in 51% yield. However, when NO2 was replaced by C(O)OEt, the reaction proceeded with the formation of bisperoxide 182 (Scheme 65) [163] . This is probably due to the fact that the ester group has lower electron-withdrawing properties. However, when NO 2 was replaced by C(O)OEt, the reaction proceeded with the formation of bisperoxide 182 (Scheme 65) [163] . This is probably due to the fact that the ester group has lower electron-withdrawing properties. Presumably, the reaction proceeds along the following route: the first stage of the reaction involves the opening of the ozonide cycle in 188 under the action of BF3·Et2O with Presumably, the reaction proceeds along the following route: the first stage of the reaction involves the opening of the ozonide cycle in 188 under the action of BF 3 ·Et 2 O with the formation of a BF 3 -coordinated intermediate A, containing a peroxide fragment. The attack of intermediate A at the alkene 189 is accompanied by the formation of two intermediates, B and C, which, in turn, leads to ring closure and gives 1,2-dioxolane. However, the rate of ring closure is much slower than the rotation of the C-C bond, so the formation of four isomeric products occurs. The mechanism in Scheme 68 illustrates that the ratio of (190d + 190e) to (190f + 190g) corresponds to the ratio of the two approaches of BF 3 -coordinated intermediate A to alkene. Also, boron trifluoride etherate is efficient for the synthesis of 1,2,4,5-tetraoxanes 201 from gem-bisperoxides 199 and orthoformates 200 (Scheme 72) [170] . The trans-isomer 201 was the major product in all cases as determined by NMR, while the cis-isomer was found only in trace amounts. The reaction was carried out in dichloromethane at room temperature. This approach was the first method for the preparation of tetraoxanes cis-201 and trans-201 with an alkoxy substituent. In the study on the synthesis of pharmacologically important endoperoxides, peroxide 204 was synthesized from substituted aldehydes 202; boron trifluoride etherate was used as a catalyst in this reaction. Condensation of peroxide 203 with betulin aldehydes 202 in the presence of BF3·Et2O led to the assembly of peroxides 204. The yield of the target peroxide was low, and the resulting diastereoisomers could not be separated. Unfortunately, mixtures of isomers did not show significant anticancer activity (Scheme 73) [171] . Also, boron trifluoride etherate is efficient for the synthesis of 1,2,4,5-tetraoxanes 201 from gem-bisperoxides 199 and orthoformates 200 (Scheme 72) [170] . The trans-isomer 201 was the major product in all cases as determined by NMR, while the cis-isomer was found only in trace amounts. The reaction was carried out in dichloromethane at room temperature. This approach was the first method for the preparation of tetraoxanes cis-201 and trans-201 with an alkoxy substituent. In the study on the synthesis of pharmacologically important endoperoxides, peroxide 204 was synthesized from substituted aldehydes 202; boron trifluoride etherate was used as a catalyst in this reaction. Condensation of peroxide 203 with betulin aldehydes 202 in the presence of BF3·Et2O led to the assembly of peroxides 204. The yield of the target peroxide was low, and the resulting diastereoisomers could not be separated. Unfortunately, mixtures of isomers did not show significant anticancer activity (Scheme 73) [171] . Also, boron trifluoride etherate is efficient for the synthesis of 1,2,4,5-tetraoxanes 201 from gem-bisperoxides 199 and orthoformates 200 (Scheme 72) [170] . The trans-isomer 201 was the major product in all cases as determined by NMR, while the cis-isomer was found only in trace amounts. The reaction was carried out in dichloromethane at room temperature. This approach was the first method for the preparation of tetraoxanes cis-201 and trans-201 with an alkoxy substituent. Also, boron trifluoride etherate is efficient for the synthesis of 1,2,4,5-tetraoxanes 201 from gem-bisperoxides 199 and orthoformates 200 (Scheme 72) [170] . The trans-isomer 201 was the major product in all cases as determined by NMR, while the cis-isomer was found only in trace amounts. The reaction was carried out in dichloromethane at room temperature. This approach was the first method for the preparation of tetraoxanes cis-201 and trans-201 with an alkoxy substituent. In the study on the synthesis of pharmacologically important endoperoxides, peroxide 204 was synthesized from substituted aldehydes 202; boron trifluoride etherate was used as a catalyst in this reaction. Condensation of peroxide 203 with betulin aldehydes 202 in the presence of BF3·Et2O led to the assembly of peroxides 204. The yield of the target peroxide was low, and the resulting diastereoisomers could not be separated. Unfortunately, mixtures of isomers did not show significant anticancer activity (Scheme 73) [171] . Cyclic peroxides 207 can be obtained from hydroperoxides 205 and ketones 206 in the presence of boron trifluoride etherate in up to 17% yield (Scheme 74) [130] . The yield of the target peroxides 207 was in the same range as when using In(OTf)3 as a catalyst (see Scheme 33) . However, BF3·Et2O is less expensive than In(OTf)3. The reaction of 1,1′-bishydroperoxy(cycloalkyl)peroxides 209 with ketals 208 in the presence of BF3·Et2O afforded 1,2,4,5,7,8-hexaoxonanes 210 in up to 94% yields (Scheme 75) [172] . This approach is convenient and simple for the synthesis of 1,2,4,5,7,8-hexaoxonanes, which significantly expands the structural diversity of these compounds and, in most cases, allows them to be synthesized in high yield. Cyclic peroxides 207 can be obtained from hydroperoxides 205 and ketones 206 in the presence of boron trifluoride etherate in up to 17% yield (Scheme 74) [130] . The yield of the target peroxides 207 was in the same range as when using In(OTf) 3 as a catalyst (see Scheme 33) . However, BF 3 ·Et 2 O is less expensive than In(OTf) 3 . Cyclic peroxides 207 can be obtained from hydroperoxides 205 and ketones 206 in the presence of boron trifluoride etherate in up to 17% yield (Scheme 74) [130] . The yield of the target peroxides 207 was in the same range as when using In(OTf)3 as a catalyst (see Scheme 33) . However, BF3·Et2O is less expensive than In(OTf)3. The reaction of 1,1′-bishydroperoxy(cycloalkyl)peroxides 209 with ketals 208 in the presence of BF3·Et2O afforded 1,2,4,5,7,8-hexaoxonanes 210 in up to 94% yields (Scheme 75) [172] . This approach is convenient and simple for the synthesis of 1,2,4,5,7,8-hexaoxonanes, which significantly expands the structural diversity of these compounds and, in most cases, allows them to be synthesized in high yield. The reaction of 1,1 -bishydroperoxy(cycloalkyl)peroxides 209 with ketals 208 in the presence of BF 3 ·Et 2 O afforded 1,2,4,5,7,8-hexaoxonanes 210 in up to 94% yields (Scheme 75) [172] . This approach is convenient and simple for the synthesis of 1,2,4,5,7,8-hexaoxonanes, which significantly expands the structural diversity of these compounds and, in most cases, allows them to be synthesized in high yield. Cyclic peroxides 207 can be obtained from hydroperoxides 205 and ketones 206 in the presence of boron trifluoride etherate in up to 17% yield (Scheme 74) [130] . The yield of the target peroxides 207 was in the same range as when using In(OTf)3 as a catalyst (see Scheme 33) . However, BF3·Et2O is less expensive than In(OTf)3. The reaction of 1,1′-bishydroperoxy(cycloalkyl)peroxides 209 with ketals 208 in the presence of BF3·Et2O afforded 1,2,4,5,7,8-hexaoxonanes 210 in up to 94% yields (Scheme 75) [172] . This approach is convenient and simple for the synthesis of 1,2,4,5,7,8-hexaoxonanes, which significantly expands the structural diversity of these compounds and, in most cases, allows them to be synthesized in high yield. A convenient, experimentally simple and selective method was developed for the synthesis of bridged 1,2,4,5-tetraoxanes based on the reaction of hydrogen peroxide with β-diketone 213 catalyzed by strong acids (H2SO4, HClO4, HBF4) with a yield of 49-77% (Scheme 77) [37, 76] . This process can also proceed with the use of Lewis acid (BF3·Et2O). For example, tetraoxane 214 was obtained in 64% yield [76] . The method for the synthesis of ozonides 216 and 217 from 1,5-diketones 215 and hydrogen peroxide, which does not require the use of toxic ozone, was reported (Scheme 78) [84, 174] . It was found that the interaction of 1,5-diketones 215 with H2O2, in the presence of BF3·Et2O leads to the selective assembly of stereoisomeric ozonides 216 and 217. Peroxides 216 and 217 exhibit antimalarial [175] and anticancer [175, 176] activity. Recently a new class of peroxides, namely β-hydroperoxy-β-peroxylactones 221, was discovered. They were obtained by the peroxidation of β-ketoesters 218 and their derivatives 219 and 220 (silylenol ethers, alkylene ethers, enol acetates, cyclic acetals) with the H2O2/BF3·Et2O system. The reaction proceeded with the formation of β-hydroperoxy-βperoxylactones in a yield of 30-96% (Scheme 79) [85, 177] . These β-peroxylactones are stable and can be useful for further synthetic transformations. A convenient, experimentally simple and selective method was developed for the synthesis of bridged 1,2,4,5-tetraoxanes based on the reaction of hydrogen peroxide with β-diketone 213 catalyzed by strong acids (H 2 SO 4 , HClO 4 , HBF 4 ) with a yield of 49-77% (Scheme 77) [37, 76] . This process can also proceed with the use of Lewis acid (BF 3 ·Et 2 O). For example, tetraoxane 214 was obtained in 64% yield [76] . A convenient, experimentally simple and selective method was developed for the synthesis of bridged 1,2,4,5-tetraoxanes based on the reaction of hydrogen peroxide with β-diketone 213 catalyzed by strong acids (H2SO4, HClO4, HBF4) with a yield of 49-77% (Scheme 77) [37, 76] . This process can also proceed with the use of Lewis acid (BF3·Et2O). For example, tetraoxane 214 was obtained in 64% yield [76] . The method for the synthesis of ozonides 216 and 217 from 1,5-diketones 215 and hydrogen peroxide, which does not require the use of toxic ozone, was reported (Scheme 78) [84, 174] . It was found that the interaction of 1,5-diketones 215 with H2O2, in the presence of BF3·Et2O leads to the selective assembly of stereoisomeric ozonides 216 and 217. Peroxides 216 and 217 exhibit antimalarial [175] and anticancer [175, 176] activity. Recently a new class of peroxides, namely β-hydroperoxy-β-peroxylactones 221, was discovered. They were obtained by the peroxidation of β-ketoesters 218 and their derivatives 219 and 220 (silylenol ethers, alkylene ethers, enol acetates, cyclic acetals) with the H2O2/BF3·Et2O system. The reaction proceeded with the formation of β-hydroperoxy-βperoxylactones in a yield of 30-96% (Scheme 79) [85, 177] . These β-peroxylactones are stable and can be useful for further synthetic transformations. The method for the synthesis of ozonides 216 and 217 from 1,5-diketones 215 and hydrogen peroxide, which does not require the use of toxic ozone, was reported (Scheme 78) [84, 174] . It was found that the interaction of 1,5-diketones 215 with H 2 O 2 , in the presence of BF 3 ·Et 2 O leads to the selective assembly of stereoisomeric ozonides 216 and 217. Peroxides 216 and 217 exhibit antimalarial [175] and anticancer [175, 176] activity. A convenient, experimentally simple and selective method was developed for the synthesis of bridged 1,2,4,5-tetraoxanes based on the reaction of hydrogen peroxide with β-diketone 213 catalyzed by strong acids (H2SO4, HClO4, HBF4) with a yield of 49-77% (Scheme 77) [37, 76] . This process can also proceed with the use of Lewis acid (BF3·Et2O). For example, tetraoxane 214 was obtained in 64% yield [76] . The method for the synthesis of ozonides 216 and 217 from 1,5-diketones 215 and hydrogen peroxide, which does not require the use of toxic ozone, was reported (Scheme 78) [84, 174] . It was found that the interaction of 1,5-diketones 215 with H2O2, in the presence of BF3·Et2O leads to the selective assembly of stereoisomeric ozonides 216 and 217. Peroxides 216 and 217 exhibit antimalarial [175] and anticancer [175, 176] activity. Recently a new class of peroxides, namely β-hydroperoxy-β-peroxylactones 221, was discovered. They were obtained by the peroxidation of β-ketoesters 218 and their derivatives 219 and 220 (silylenol ethers, alkylene ethers, enol acetates, cyclic acetals) with the H2O2/BF3·Et2O system. The reaction proceeded with the formation of β-hydroperoxy-βperoxylactones in a yield of 30-96% (Scheme 79) [85, 177] . These β-peroxylactones are stable and can be useful for further synthetic transformations. Recently a new class of peroxides, namely β-hydroperoxy-β-peroxylactones 221, was discovered. They were obtained by the peroxidation of β-ketoesters 218 and their derivatives 219 and 220 (silylenol ethers, alkylene ethers, enol acetates, cyclic acetals) with the H 2 O 2 /BF 3 ·Et 2 O system. The reaction proceeded with the formation of β-hydroperoxyβ-peroxylactones in a yield of 30-96% (Scheme 79) [85, 177] . These β-peroxylactones are stable and can be useful for further synthetic transformations. In continuation of studies in this direction, the BF3·Et2O/H2O2 system was applied to the γ-ketoesters 224. Peroxidation proceeded with the formation of cyclic γ-hydroperoxyγ-peroxylactones 225 in 44-83% yields (Scheme 81) [179] . In continuation of studies in this direction, the BF3·Et2O/H2O2 system was applied to the γ-ketoesters 224. Peroxidation proceeded with the formation of cyclic γ-hydroperoxyγ-peroxylactones 225 in 44-83% yields (Scheme 81) [179] . In continuation of studies in this direction, the BF 3 ·Et 2 O/H 2 O 2 system was applied to the γ-ketoesters 224. Peroxidation proceeded with the formation of cyclic γ-hydroperoxyγ-peroxylactones 225 in 44-83% yields (Scheme 81) [179] . Tricyclic monoperoxides 227 were obtained by the peroxidation of β,δ -triketones 226 with the H 2 O 2 /BF 3 ·Et 2 O system (Scheme 82) [81, 86] . Peroxidation was carried out under mild conditions at room temperature for 1 h. Despite the presence of three carbonyl groups, peroxidation proceeded selectively with the formation of cyclic product 227. The yield of target peroxides 227 was 48-93%. It was found that the tricyclic monoperoxide exhibits a high in vitro and in vivo anthelmintic activity against S. mansoni. Scheme 80. Synthesis of β-alkoxy-β-peroxylactones 223. In continuation of studies in this direction, the BF3·Et2O/H2O2 system was applied to the γ-ketoesters 224. Peroxidation proceeded with the formation of cyclic γ-hydroperoxyγ-peroxylactones 225 in 44-83% yields (Scheme 81) [179] . Tricyclic monoperoxides 227 were obtained by the peroxidation of β,δ′-triketones 226 with the H2O2/BF3·Et2O system (Scheme 82) [81, 86] . Peroxidation was carried out under mild conditions at room temperature for 1 h. Despite the presence of three carbonyl groups, peroxidation proceeded selectively with the formation of cyclic product 227. The yield of target peroxides 227 was 48-93%. It was found that the tricyclic monoperoxide exhibits a high in vitro and in vivo anthelmintic activity against S. mansoni. The first total synthesis of natural bioactive azaperoxides Verruculogen 230a and Fumitremorgin A 230b was developed in 2015 by the Baran group [180] . The final step included the catalyzed by BF3·Et2O condensation of aldehyde 229 with peroxide 228 (Scheme 83). Iodine in the synthesis of organic peroxides can act as both a catalyst and a reagent. The presence of iodine can activate substrates via halogen bonding (acts as Lewis acid), iodonium(I) species or formation of "hidden" HI Broensted acid [181] [182] [183] [184] [185] [186] [187] . The interaction of alkenes 231 with hydroperoxide in the presence of molecular iodine makes it possible to obtain vicinal iodoperoxyalkanes 232 (Scheme 84) [188] . This reaction was carried out Tricyclic monoperoxides 227 were obtained by the peroxidation of β,δ′-triketones 226 with the H2O2/BF3·Et2O system (Scheme 82) [81, 86] . Peroxidation was carried out under mild conditions at room temperature for 1 h. Despite the presence of three carbonyl groups, peroxidation proceeded selectively with the formation of cyclic product 227. The yield of target peroxides 227 was 48-93%. It was found that the tricyclic monoperoxide exhibits a high in vitro and in vivo anthelmintic activity against S. mansoni. The first total synthesis of natural bioactive azaperoxides Verruculogen 230a and Fumitremorgin A 230b was developed in 2015 by the Baran group [180] . The final step included the catalyzed by BF3·Et2O condensation of aldehyde 229 with peroxide 228 (Scheme 83). Iodine in the synthesis of organic peroxides can act as both a catalyst and a reagent. The presence of iodine can activate substrates via halogen bonding (acts as Lewis acid), iodonium(I) species or formation of "hidden" HI Broensted acid [181] [182] [183] [184] [185] [186] [187] . The interaction Iodine in the synthesis of organic peroxides can act as both a catalyst and a reagent. The presence of iodine can activate substrates via halogen bonding (acts as Lewis acid), iodonium(I) species or formation of "hidden" HI Broensted acid [181] [182] [183] [184] [185] [186] [187] . The interaction of alkenes 231 with hydroperoxide in the presence of molecular iodine makes it possible to obtain vicinal iodoperoxyalkanes 232 (Scheme 84) [188] . This reaction was carried out with 0.7 eq. iodine and 4 eq. hydroperoxide in diethyl ether or dichloromethane at room temperature. Depending on the reactivity of the hydroperoxide, the reaction time was from 5 to 72 h. The mechanism of the formation of iodoperoxyalkanes and iodoalkanols is shown in Scheme 85. Presumably, the formation of iodoperoxyalkane can proceed along path A or B. Path A corresponds to the classical scheme of sequential addition of electrophilic iodine and nucleophilic hydroperoxide to the double bond. Path B is based on experimental data according to which an increase in the amount of iodine (a nucleophile competing with tert-butyl hydroperoxide) leads to an increase in the yield of 1-(tert-butylperoxy)-2-iodocyclohexane, while the expected 1,2-diiodocyclohexane is formed in trace amounts. Iodoperoxide appears to be formed by pathway B through a previously unknown process. Initially, the reaction forms 1,2-diiodocyclohexane, which is converted by iodine to intermediate Y, which contains a partially positive charge on the carbon atoms. The latter reacts with hydroperoxide. The cyclization of unsaturated hydroperoxyacetal 234 was performed using systems such as pyridine/I2 or t-BuOK/I2. The use of the latter made it possible to obtain 1,2-dioxanes 235 in a yield up to 85% (Scheme 86) [189] . The mechanism of the formation of iodoperoxyalkanes and iodoalkanols is shown in Scheme 85. Presumably, the formation of iodoperoxyalkane can proceed along path A or B. Path A corresponds to the classical scheme of sequential addition of electrophilic iodine and nucleophilic hydroperoxide to the double bond. Path B is based on experimental data according to which an increase in the amount of iodine (a nucleophile competing with tert-butyl hydroperoxide) leads to an increase in the yield of 1-(tert-butylperoxy)-2iodocyclohexane, while the expected 1,2-diiodocyclohexane is formed in trace amounts. Iodoperoxide appears to be formed by pathway B through a previously unknown process. Initially, the reaction forms 1,2-diiodocyclohexane, which is converted by iodine to intermediate Y, which contains a partially positive charge on the carbon atoms. The latter reacts with hydroperoxide. The mechanism of the formation of iodoperoxyalkanes and iodoalkanols is shown in Scheme 85. Presumably, the formation of iodoperoxyalkane can proceed along path A or B. Path A corresponds to the classical scheme of sequential addition of electrophilic iodine and nucleophilic hydroperoxide to the double bond. Path B is based on experimental data according to which an increase in the amount of iodine (a nucleophile competing with tert-butyl hydroperoxide) leads to an increase in the yield of 1-(tert-butylperoxy)-2-iodocyclohexane, while the expected 1,2-diiodocyclohexane is formed in trace amounts. Iodoperoxide appears to be formed by pathway B through a previously unknown process. Initially, the reaction forms 1,2-diiodocyclohexane, which is converted by iodine to intermediate Y, which contains a partially positive charge on the carbon atoms. The latter reacts with hydroperoxide. The cyclization of unsaturated hydroperoxyacetal 234 was performed using systems such as pyridine/I2 or t-BuOK/I2. The use of the latter made it possible to obtain 1,2-dioxanes 235 in a yield up to 85% (Scheme 86) [189] . The cyclization of unsaturated hydroperoxyacetal 234 was performed using systems such as pyridine/I 2 or t-BuOK/I 2 . The use of the latter made it possible to obtain 1,2dioxanes 235 in a yield up to 85% (Scheme 86) [189] . However, the use of the pyridine/I2 system for unsaturated hydroperoxyacetal 236 did not provide the assembly of 1,2,4-trioxane 237. The t-BuOK/I2 system, which performed well in the assembly of 1,2-dioxalane 235 (Scheme 87), led to peroxide 237, but in low yield. Cyclization 236 under the action of the KH/I2 system also proceeded in a low yield (Scheme 87) [189] . Using 30% aq. H2O2 and iodine as a catalyst, geminal bishydroperoxides 239 were obtained from cyclic and acyclic ketones 238 in a yield of 50 to 98% (Scheme 88). All geminal bishydroperoxides 239 exhibit pronounced in vitro antimicrobial and antifungal activity against B. cereus, E. coli, P. aeruginosa, S. aureus, C. albicans, and A. niger [190] . However, the use of the pyridine/I 2 system for unsaturated hydroperoxyacetal 236 did not provide the assembly of 1,2,4-trioxane 237. The t-BuOK/I 2 system, which performed well in the assembly of 1,2-dioxalane 235 (Scheme 87), led to peroxide 237, but in low yield. Cyclization 236 under the action of the KH/I 2 system also proceeded in a low yield (Scheme 87) [189] . However, the use of the pyridine/I2 system for unsaturated hydroperoxyacetal 236 did not provide the assembly of 1,2,4-trioxane 237. The t-BuOK/I2 system, which performed well in the assembly of 1,2-dioxalane 235 (Scheme 87), led to peroxide 237, but in low yield. Cyclization 236 under the action of the KH/I2 system also proceeded in a low yield (Scheme 87) [189] . Using 30% aq. H2O2 and iodine as a catalyst, geminal bishydroperoxides 239 were obtained from cyclic and acyclic ketones 238 in a yield of 50 to 98% (Scheme 88). All geminal bishydroperoxides 239 exhibit pronounced in vitro antimicrobial and antifungal activity against B. cereus, E. coli, P. aeruginosa, S. aureus, C. albicans, and A. niger [190] . Using 30% aq. H 2 O 2 and iodine as a catalyst, geminal bishydroperoxides 239 were obtained from cyclic and acyclic ketones 238 in a yield of 50 to 98% (Scheme 88). All geminal bishydroperoxides 239 exhibit pronounced in vitro antimicrobial and antifungal activity against B. cereus, E. coli, P. aeruginosa, S. aureus, C. albicans, and A. niger [190] . However, the use of the pyridine/I2 system for unsaturated hydroperoxyacetal 236 did not provide the assembly of 1,2,4-trioxane 237. The t-BuOK/I2 system, which performed well in the assembly of 1,2-dioxalane 235 (Scheme 87), led to peroxide 237, but in low yield. Cyclization 236 under the action of the KH/I2 system also proceeded in a low yield (Scheme 87) [189] . Using 30% aq. H2O2 and iodine as a catalyst, geminal bishydroperoxides 239 were obtained from cyclic and acyclic ketones 238 in a yield of 50 to 98% (Scheme 88). All geminal bishydroperoxides 239 exhibit pronounced in vitro antimicrobial and antifungal activity against B. cereus, E. coli, P. aeruginosa, S. aureus, C. albicans, and A. niger [190] . This approach was also used in the synthesis of bishydroxyperoxides 241 from acetophenone and benzaldehydes 240. Unfortunately, peroxidation of compounds containing an electron-withdrawing substituent in the ring did not lead to the target geminal bishydroxyperoxides (Scheme 89) [190] . This approach was also used in the synthesis of bishydroxyperoxides 241 from acetophenone and benzaldehydes 240. Unfortunately, peroxidation of compounds containing an electron-withdrawing substituent in the ring did not lead to the target geminal bishydroxyperoxides (Scheme 89) [190] . The action of iodine as a Lewis acid is based on its interaction with the oxygen atom of the carbonyl group of 240, which facilitates the nucleophilic attack of hydrogen peroxide on the neighboring carbon atom. Iodine then eliminates the hydroxy group from the sp 3 -carbon atom of intermediate A and the peroxycarbenium ion B is formed, which is attacked by the second hydrogen peroxide molecule to form the final product 241. The last stage of this mechanism is irreversible (Scheme 90). The action of iodine as a Lewis acid is based on its interaction with the oxygen atom of the carbonyl group of 240, which facilitates the nucleophilic attack of hydrogen peroxide on the neighboring carbon atom. Iodine then eliminates the hydroxy group from the sp 3 -carbon atom of intermediate A and the peroxycarbenium ion B is formed, which is attacked by the second hydrogen peroxide molecule to form the final product 241. The last stage of this mechanism is irreversible (Scheme 90). This approach was also used in the synthesis of bishydroxyperoxides 241 from acetophenone and benzaldehydes 240. Unfortunately, peroxidation of compounds containing an electron-withdrawing substituent in the ring did not lead to the target geminal bishydroxyperoxides (Scheme 89) [190] . The action of iodine as a Lewis acid is based on its interaction with the oxygen atom of the carbonyl group of 240, which facilitates the nucleophilic attack of hydrogen peroxide on the neighboring carbon atom. Iodine then eliminates the hydroxy group from the sp 3 -carbon atom of intermediate A and the peroxycarbenium ion B is formed, which is attacked by the second hydrogen peroxide molecule to form the final product 241. The last stage of this mechanism is irreversible (Scheme 90). The iodine-catalyzed peroxidation of carbonyl compounds 242 (acyclic and cyclic ketones and aromatic aldehydes), is a simple and effective approach to obtain geminal hydroperoxides 244 and geminal tert-butyl peroxides 246. A similar reaction in methanol led to hydroperoxyacetals 243 and tert-butylperoxyacetals 245 (Scheme 91) [90] . The application of I 2 /H 2 O 2 and I 2 /TBHP systems to non-aromatic aldehydes allows one to obtain hydroxy-hydroperoxides 248 and tert-butylhydroxyperoxides 249 (Scheme 92) [190] . Iodine-catalyzed peroxidation of enol ethers 250 and 253 in Et 2 O led to formation of 2-iodo-1-methoxy hydroperoxides 251 and 254, respectively, with a yield of 32-41% (Scheme 93) [191] . α-Iodo ketones 252 and 255 were formed as byproducts. Peroxidation of monocyclic enol ethers 256 under the action of the I 2 /H 2 O 2 system proceeded with the formation of iodo-hydroperoxides 257 and α-iodo hemiacetals 258, while the reaction with I 2 /ROOH led only to iodoperoxides 259 (Scheme 94) [192] . The application of I2/H2O2 and I2/TBHP systems to non-aromatic aldehydes allows one to obtain hydroxy-hydroperoxides 248 and tert-butylhydroxyperoxides 249 (Scheme 92) [190] . Iodine-catalyzed peroxidation of enol ethers 250 and 253 in Et2O led to formation of 2-iodo-1-methoxy hydroperoxides 251 and 254, respectively, with a yield of 32-41% (Scheme 93) [191] . α-Iodo ketones 252 and 255 were formed as byproducts. Iodine-catalyzed peroxidation of enol ethers 250 and 253 in Et2O led to formation of 2-iodo-1-methoxy hydroperoxides 251 and 254, respectively, with a yield of 32-41% (Scheme 93) [191] . α-Iodo ketones 252 and 255 were formed as byproducts. Peroxidation of monocyclic enol ethers 256 under the action of the I2/H2O2 system proceeded with the formation of iodo-hydroperoxides 257 and α-iodo hemiacetals 258, while the reaction with I2/ROOH led only to iodoperoxides 259 (Scheme 94) [192] . Iodine-catalyzed peroxidation of enol ethers 250 and 253 in Et2O led to formation of 2-iodo-1-methoxy hydroperoxides 251 and 254, respectively, with a yield of 32-41% (Scheme 93) [191] . α-Iodo ketones 252 and 255 were formed as byproducts. Peroxidation of monocyclic enol ethers 256 under the action of the I2/H2O2 system proceeded with the formation of iodo-hydroperoxides 257 and α-iodo hemiacetals 258, while the reaction with I2/ROOH led only to iodoperoxides 259 (Scheme 94) [192] . The previously unknown 1-hydroperoxy-1′-alkoxyperoxides 265 were synthesized in 45-64% yield by iodine-catalyzed reaction of geminal bishydroperoxides 263 with acetals 264 (Scheme 96) [193] . The nature of the solvent has a decisive influence on the yield of the target peroxides. Good results were obtained in such solvents as Et2O and THF. The formation of cyclic peroxides was not observed. 1-Hydroperoxy-1′-alkoxyperoxides 265 were readily isolated from the reaction mixture by column chromatography. The previously unknown 1-hydroperoxy-1 -alkoxyperoxides 265 were synthesized in 45-64% yield by iodine-catalyzed reaction of geminal bishydroperoxides 263 with acetals 264 (Scheme 96) [193] . The nature of the solvent has a decisive influence on the yield of the target peroxides. Good results were obtained in such solvents as Et 2 O and THF. The formation of cyclic peroxides was not observed. 1-Hydroperoxy-1 -alkoxyperoxides 265 were readily isolated from the reaction mixture by column chromatography. The previously unknown 1-hydroperoxy-1′-alkoxyperoxides 265 were synthesized in 45-64% yield by iodine-catalyzed reaction of geminal bishydroperoxides 263 with acetals 264 (Scheme 96) [193] . The nature of the solvent has a decisive influence on the yield of the target peroxides. Good results were obtained in such solvents as Et2O and THF. The formation of cyclic peroxides was not observed. 1-Hydroperoxy-1′-alkoxyperoxides 265 were readily isolated from the reaction mixture by column chromatography. Also, 1-hydroperoxy-1 -alkoxyperoxides 265 are formed by the interaction of bishydroperoxides 263 with enol ethers 266 in the presence of molecular iodine (Scheme 97) [193] . The previously unknown 1-hydroperoxy-1′-alkoxyperoxides 265 were synthesized in 45-64% yield by iodine-catalyzed reaction of geminal bishydroperoxides 263 with acetals 264 (Scheme 96) [193] . The nature of the solvent has a decisive influence on the yield of the target peroxides. Good results were obtained in such solvents as Et2O and THF. The formation of cyclic peroxides was not observed. 1-Hydroperoxy-1′-alkoxyperoxides 265 were readily isolated from the reaction mixture by column chromatography. Peroxidation of 2-allyl-1,3-diketones 267 under the action of the I2/H2O2 led to the formation of diastreoisomeric bicyclic peroxides 269 and 270 (Scheme 99) [194] . The reaction was carried out under mild conditions in dichloromethane at 20-25 °C with the use of a five-fold molar excess of H2O2 and a two-fold excess of I2 with respect to the starting diketone. It should be noted that the expected bridged tetraoxanes were not found during the peroxidation of 1,3-diketones 267. Diastereomeric iodine peroxides 269 and 270 were obtained as a mixture of diastereoisomers with a yield of 50 to 81%. The interaction of ketones 267 containing an aromatic ring adjacent to the carbonyl group with the I2/H2O2 system led to the formation of iodides 268 with a yield of 11-24%, but not to the bicyclic peroxides 269 and 270. Scheme 98. The proposed mechanism for the assembly of 1-hydroperoxy-1 -alkoxyperoxides 265. Peroxidation of 2-allyl-1,3-diketones 267 under the action of the I 2 /H 2 O 2 led to the formation of diastreoisomeric bicyclic peroxides 269 and 270 (Scheme 99) [194] . The reaction was carried out under mild conditions in dichloromethane at 20-25 • C with the use of a five-fold molar excess of H 2 O 2 and a two-fold excess of I 2 with respect to the starting diketone. It should be noted that the expected bridged tetraoxanes were not found during the peroxidation of 1,3-diketones 267. Diastereomeric iodine peroxides 269 and 270 were obtained as a mixture of diastereoisomers with a yield of 50 to 81%. The interaction of ketones 267 containing an aromatic ring adjacent to the carbonyl group with the I 2 /H 2 O 2 system led to the formation of iodides 268 with a yield of 11-24%, but not to the bicyclic peroxides 269 and 270. of a five-fold molar excess of H2O2 and a two-fold excess of I2 with respect to the starting diketone. It should be noted that the expected bridged tetraoxanes were not found during the peroxidation of 1,3-diketones 267. Diastereomeric iodine peroxides 269 and 270 were obtained as a mixture of diastereoisomers with a yield of 50 to 81%. The interaction of ketones 267 containing an aromatic ring adjacent to the carbonyl group with the I2/H2O2 system led to the formation of iodides 268 with a yield of 11-24%, but not to the bicyclic peroxides 269 and 270. Scheme 99. Synthesis of diastereomeric bicyclic peroxides 269 and 270. The first stage involves the interaction of iodine with a double bond to form the iodonium cation A, which undergoes cyclization to the intermediate tetrahydrofuran B, stabilized by the anomeric effect [66] [67] [68] (Scheme 100). Then H2O2 attacks B with the formation of iodoperoxide C, which undergoes cyclization with the formation of 269 + 270. In the case of compounds containing an aryl substituent at the carbonyl group, peroxide C is protonated with the formation of D, which undergoes Baeyer-Villiger rearrangement to form cation E, which is iodinated by HI to form 268. [195] . This method allows for the obtaining of cyclic triperoxides in good yields from 51 to 82%. Scheme 100. The proposed mechanism for the assembly of bicyclic peroxides 269 and 270. A method was proposed for the synthesis of 1,2,4,5,7,8-hexaoxananes 273, based on the I2-catalyzed reaction of acetals 271 with 1,1′-dihydroperoxydi(cycloalkyl) peroxides 272 (Scheme 101) [195] . This method allows for the obtaining of cyclic triperoxides in good yields from 51 to 82%. A convenient method has been developed for the synthesis of symmetric 1,2,4,5tetraoxanes 276 from carbonyl compounds 274 and peroxidizing agent bis(trimethylsilyl) peroxide 275 in the presence of 1 equiv. of TMSOTf. The reaction was carried out at 0 °C in acetonitrile or at −70 °C in CH2Cl2 (Scheme 102) [196] . The in vitro and in vivo studies demonstrated that these types of cyclic peroxides are active against P. falciparum [197] . A convenient method has been developed for the synthesis of symmetric 1,2,4,5tetraoxanes 276 from carbonyl compounds 274 and peroxidizing agent bis(trimethylsilyl) peroxide 275 in the presence of 1 equiv. of TMSOTf. The reaction was carried out at 0 • C in acetonitrile or at −70 • C in CH 2 Cl 2 (Scheme 102) [196] . The in vitro and in vivo studies demonstrated that these types of cyclic peroxides are active against P. falciparum [197] . Peroxidation of carbonyl compounds with the use of Me3SiOOSiMe3/TMSOTf system allows one to obtain steroidal tetraoxanes 278 (Scheme 103) [198] . The reaction was carried out at 0 °C in acetonitrile using a 1.5-fold molar excess of Me3SiOOSiMe3 and TMSOTf with respect to ketone 277. Peroxidation of carbonyl compounds with the use of Me 3 SiOOSiMe 3 /TMSOTf system allows one to obtain steroidal tetraoxanes 278 (Scheme 103) [198] . The reaction was carried out at 0 • C in acetonitrile using a 1.5-fold molar excess of Me 3 SiOOSiMe 3 and TMSOTf with respect to ketone 277. The synthesis of unsymmetrical 1,2,4,5-tetraoxanes 282 proceeds through the interaction of geminal bis(trimethylsilyl)peroxides 280 with carbonyl compounds 281 in the presence of TMSOTf. 1,2,4,5-Tetraoxanes 282 are formed in yields up to 53% (Scheme 104) [197] . Corresponding bis(trimethylsilyl) peroxides 280 were obtained by the interaction of geminal bishydroperoxides 279 with BSA (N, O-bis (trimethylsilyl) acetamide) in 50-67% yield. In addition, TMSOTf is used as a catalyst in the synthesis of 1,2,4,5-tetraoxepanes 286 by the reaction of 1,2-bis (trimethylsilyl) peroxide 284 with carbonyl compounds 285 (Scheme 105) [197, 199] . Silyl peroxide 284 was synthesized by reaction of BSA (N, O-bis (trimethylsilyl) acetamide) on 1,2-dihydroperoxide 283 in 56% yield. Peroxidation of carbonyl compounds with the use of Me3SiOOSiMe3/TMSOTf system allows one to obtain steroidal tetraoxanes 278 (Scheme 103) [198] . The reaction was carried out at 0 °C in acetonitrile using a 1.5-fold molar excess of Me3SiOOSiMe3 and TMSOTf with respect to ketone 277. Scheme In addition, TMSOTf is used as a catalyst in the synthesis of 1,2,4,5-tetraoxep by the reaction of 1,2-bis (trimethylsilyl) peroxide 284 with carbonyl compou (Scheme 105) [197, 199] . Silyl peroxide 284 was synthesized by reaction of BSA (N (trimethylsilyl) acetamide) on 1,2-dihydroperoxide 283 in 56% yield. In addition, TMSOTf is used as a catalyst in the synthesis of 1,2,4,5-tetraoxepanes 286 by the reaction of 1,2-bis (trimethylsilyl) peroxide 284 with carbonyl compounds 285 (Scheme 105) [197, 199] . Silyl peroxide 284 was synthesized by reaction of BSA (N, O-bis (trimethylsilyl) acetamide) on 1,2-dihydroperoxide 283 in 56% yield. The developed system TMSOTf/H 2 O 2 for oxetane ring opening in 290 was successfully used at one of the stages in the total synthesis of plakinic acid A cis-292 and trans-292, a natural compound with antitumor activity (Scheme 107) [111] . Opening of the oxetane ring in 290 by TMSOTf resulted in the formation of readily separable 3hydroxyhydroperoxides 291 and epi-291. Then, in several steps, cyclic peroxides cis-292 and trans-292 were obtained from epi-291. Cyclic peroxolactones (1,2,4-trioxan-5-ones) 295 were obtained by the reaction of carbonyl compounds 293 with silyl peroxides 294 under the action of TfOSiMe 3 . This reaction does not proceed in the absence of TfOSiMe 3 . The synthesis was carried out in methylene chloride at a temperature of −78 • C (Scheme 108) [200, 201] . The developed system TMSOTf/H2O2 for oxetane ring opening in 290 was successfully used at one of the stages in the total synthesis of plakinic acid A cis-292 and trans-292, a natural compound with antitumor activity (Scheme 107) [111] . Opening of the oxetane ring in 290 by TMSOTf resulted in the formation of readily separable 3-hydroxyhydroperoxides 291 and epi-291. Then, in several steps, cyclic peroxides cis-292 and trans-292 were obtained from epi-291. Scheme The TMSOTf-catalyzed interaction of endoperoxides 296 and 299 with ketones 297 and 300 proceeds with the formation of above-mentioned substituted 1,2,4-trioxanes 298 and 301 with moderate to good yields (Scheme 109) [202] [203] [204] . The TMSOTf-catalyzed interaction of endoperoxides 296 and 299 with ketones 297 and 300 proceeds with the formation of above-mentioned substituted 1,2,4-trioxanes 298 and 301 with moderate to good yields (Scheme 109) [202] [203] [204] . 1,2,4-Trioxanes 304 were obtained by the reaction of diketone 303 with containing alkyl substituents endoperoxides 302 (Scheme 110) [205] . Unfortunately, the yield of target peroxides did not exceed 10%. 1,2,4-Trioxanes 304 were obtained by the reaction of diketone 303 with containing alkyl substituents endoperoxides 302 (Scheme 110) [205] . Unfortunately, the yield of target peroxides did not exceed 10%. Scheme 109. Synthesis of substituted 1,2,4-trioxanes 298 and 301. 1,2,4-Trioxanes 304 were obtained by the reaction of diketone 303 with containing alkyl substituents endoperoxides 302 (Scheme 110) [205] . Unfortunately, the yield of target peroxides did not exceed 10%. 1,2,4-Trioxanes 304 were obtained by the reaction of diketone 303 with containing alkyl substituents endoperoxides 302 (Scheme 110) [205] . Unfortunately, the yield of target peroxides did not exceed 10%. The use of TMSOTf in the reaction of endoperoxide 308 with cyclic diene 309 opened access to tetrasubstituted 1,2-dioxanes 310 (Scheme 112) [207] . At the first step, the interaction of endoperoxide 308 with TMSOTf leads to the formation of carbocation A. The subsequent attack of 1,4-diphenyl-1,3-cyclodiene B on carbocation A occurs in a regio-and diastereospecific manner. The intramolecular attack of the peroxysilyl function on the carbocation in C leads to product 310 (Scheme 113). At the first step, the interaction of endoperoxide 308 with TMSOTf leads to the formation of carbocation A. The subsequent attack of 1,4-diphenyl-1,3-cyclodiene B on carbocation A occurs in a regio-and diastereospecific manner. The intramolecular attack of the peroxysilyl function on the carbocation in C leads to product 310 (Scheme 113). The reaction of allyltrimethylsilane 312 with endoperoxides 311 in the presence of catalytic amounts of TMSOTf resulted in bicyclic 1,2-dioxanes 313 with a yield of 10% to 60% (Scheme 114) [208] . The use of TMSOTf/Et 3 SiH system in the reaction with bicyclic peroxides 314 and 316 led to unusual results. Substituted 1,2-dioxane 314 was transformed into 1,2-dioxane 315. But in the case of a 7-membered cyclic peroxide 316, the main product was bicyclic peroxide containing ozonide cycle 317 (Scheme 115) [209] . At the first step, the interaction of endoperoxide 308 with TMSOTf leads to the formation of carbocation A. The subsequent attack of 1,4-diphenyl-1,3-cyclodiene B on carbocation A occurs in a regio-and diastereospecific manner. The intramolecular attack of the peroxysilyl function on the carbocation in C leads to product 310 (Scheme 113). Scheme 113. The proposed mechanism for the assembly of tetrasubstituted 1,2-dioxanes 310. The reaction of allyltrimethylsilane 312 with endoperoxides 311 in the presence of catalytic amounts of TMSOTf resulted in bicyclic 1,2-dioxanes 313 with a yield of 10% to 60% (Scheme 114) [208] . At the first step, the interaction of endoperoxide 308 with TMSOTf leads to the formation of carbocation A. The subsequent attack of 1,4-diphenyl-1,3-cyclodiene B on carbocation A occurs in a regio-and diastereospecific manner. The intramolecular attack of the peroxysilyl function on the carbocation in C leads to product 310 (Scheme 113). REVIEW 53 But in the case of a 7-membered cyclic peroxide 316, the main product was bicyclic pe ide containing ozonide cycle 317 (Scheme 115) [209] . It has been shown that triethylsilyl hydrotrioxide 319 (Et3SiOOOH), obtained in from ozone and triethylsilane, is a mild and effective dioxetane-forming reagent from nyl ethers and vinyl thioethers on a relatively small (50-100 mg) scale. A number of s ies have demonstrated that the interaction of TBDMSOTf with dioxetane A leads t rearrangement into 1,2,4-trioxanes 320. Such peroxides exhibit in vitro antimalarial a ity, which is not inferior to peroxides like Artemisinin (Scheme 116) [210] [211] [212] . It has been shown that triethylsilyl hydrotrioxide 319 (Et 3 SiOOOH), obtained in situ from ozone and triethylsilane, is a mild and effective dioxetane-forming reagent from vinyl ethers and vinyl thioethers on a relatively small (50-100 mg) scale. A number of studies have demonstrated that the interaction of TBDMSOTf with dioxetane A leads to its rearrangement into 1,2,4-trioxanes 320. Such peroxides exhibit in vitro antimalarial activity, which is not inferior to peroxides like Artemisinin (Scheme 116) [210] [211] [212] . It has been shown that triethylsilyl hydrotrioxide 319 (Et3SiOOOH), obtained in situ from ozone and triethylsilane, is a mild and effective dioxetane-forming reagent from vinyl ethers and vinyl thioethers on a relatively small (50-100 mg) scale. A number of studies have demonstrated that the interaction of TBDMSOTf with dioxetane A leads to its rearrangement into 1,2,4-trioxanes 320. Such peroxides exhibit in vitro antimalarial activity, which is not inferior to peroxides like Artemisinin (Scheme 116) [210] [211] [212] . In a study [213] on the synthesis of cyclic peroxides 322 and 323 with high antimalarial activity, TMSOTf was used as a catalyst at the stage of peroxide cycle assembly (Scheme 117). Peroxoacetals 322 and 323 were obtained from substrate 321 in 41% yield. The antimalarial activity of peroxides 322 and 323 is comparable to the antimalarial activity of Artemisinin. In a study [213] on the synthesis of cyclic peroxides 322 and 323 with high antimalarial activity, TMSOTf was used as a catalyst at the stage of peroxide cycle assembly (Scheme 117). Peroxoacetals 322 and 323 were obtained from substrate 321 in 41% yield. The antimalarial activity of peroxides 322 and 323 is comparable to the antimalarial activity of Artemisinin. It has been shown that triethylsilyl hydrotrioxide 319 (Et3SiOOOH), obtained in situ from ozone and triethylsilane, is a mild and effective dioxetane-forming reagent from vinyl ethers and vinyl thioethers on a relatively small (50-100 mg) scale. A number of studies have demonstrated that the interaction of TBDMSOTf with dioxetane A leads to its rearrangement into 1,2,4-trioxanes 320. Such peroxides exhibit in vitro antimalarial activity, which is not inferior to peroxides like Artemisinin (Scheme 116) [210] [211] [212] . In a study [213] on the synthesis of cyclic peroxides 322 and 323 with high antimalarial activity, TMSOTf was used as a catalyst at the stage of peroxide cycle assembly (Scheme 117). Peroxoacetals 322 and 323 were obtained from substrate 321 in 41% yield. The antimalarial activity of peroxides 322 and 323 is comparable to the antimalarial activity of Artemisinin. In recent years, great interest has been paid to heteropoly acids as catalysts in the synthesis of organic peroxides. Heteropoly acids such as phosphomolybdic (PMA) and phosphotungstic (PTA) acids have a unique ability to form peroxo complexes with hydrogen peroxide and transfer the peroxide function to the substrate [37, [214] [215] [216] . The deposition of heteropoly acids on a support allows them to be reused after regeneration [37, 216] . This section covers approaches on the synthesis of bisperoxides, 1,2,4-trioxolanes, 1,2,4,5tetraoxanes, and tricyclic monoperoxides with the use of heteropoly acids. The use of the t BuOOH/H 6 P 2 W 18 O 62 system allows one to obtain dialkyl peroxides 325 from alcohols 324 in good yield (Scheme 118) [217] . In the case of secondary alcohols, the formation of an ether was observed in the reaction, which led to a decrease in the yield of the target peroxide. No by-product formation was observed in the case of tertiary alcohols. In recent years, great interest has been paid to heteropoly acids as catalysts in the synthesis of organic peroxides. Heteropoly acids such as phosphomolybdic (PMA) and phosphotungstic (PTA) acids have a unique ability to form peroxo complexes with hydrogen peroxide and transfer the peroxide function to the substrate [37, [214] [215] [216] . The deposition of heteropoly acids on a support allows them to be reused after regeneration [37, 216] . This section covers approaches on the synthesis of bisperoxides, 1,2,4-trioxolanes, 1,2,4,5-tetraoxanes, and tricyclic monoperoxides with the use of heteropoly acids. The use of the t BuOOH/H6P2W18O62 system allows one to obtain dialkyl peroxides 325 from alcohols 324 in good yield (Scheme 118) [217] . In the case of secondary alcohols, the formation of an ether was observed in the reaction, which led to a decrease in the yield of the target peroxide. No by-product formation was observed in the case of tertiary alcohols. Supported phosphotungstic acid (PTA) on zeolite (NaY) allows the synthesis of a wide range of geminal bisperoxides 327 under heterogeneous conditions with a yield of 8 to 97% (Scheme 119) [216] . Such a system (H2O2, PTA/NaY) is effective for the synthesis of 1,2,4,5-tetraoxanes 329. Target products 329 were obtained in 71% to 92% yield. Supported phosphotungstic acid (PTA) on zeolite (NaY) allows the synthesis of a wide range of geminal bisperoxides 327 under heterogeneous conditions with a yield of 8 to 97% (Scheme 119) [216] . Such a system (H 2 O 2 , PTA/NaY) is effective for the synthesis of 1,2,4,5-tetraoxanes 329. Target products 329 were obtained in 71% to 92% yield. Supported phosphotungstic acid (PTA) on zeolite (NaY) allows the synthesis of a wide range of geminal bisperoxides 327 under heterogeneous conditions with a yield of 8 to 97% (Scheme 119) [216] . Such a system (H2O2, PTA/NaY) is effective for the synthesis of 1,2,4,5-tetraoxanes 329. Target products 329 were obtained in 71% to 92% yield. In 2009, the group of Wu et. al. reported the application phosphomolybdic acid (PMA) as a catalyst for the ring-opening of epoxides with H2O2. This method gives the opportunity to obtain β-hydroperoxy alcohols 331 at ambient temperature (Scheme 120) [218] . For all tested substrates the ring-opening of epoxides 330 is highly regioselective to give the hydroperoxyl group at the quaternary carbon. In 2009, the group of Wu et. al. reported the application phosphomolybdic acid (PMA) as a catalyst for the ring-opening of epoxides with H 2 O 2 . This method gives the opportunity to obtain β-hydroperoxy alcohols 331 at ambient temperature (Scheme 120) [218] . For all tested substrates the ring-opening of epoxides 330 is highly regioselective to give the hydroperoxyl group at the quaternary carbon. The ability of heteropoly acids to form peroxo complexes and coordinate with the carbonyl group allows the peroxidation of ketones and their derivatives under milder conditions. For example, peroxidation of 1-aryl-2-allylalkane-1,3-diones 335 with I2/H2O2 system proceeds with the formation of iodinated ketoesters 336. The addition of catalytic amounts of PMA to the I2/H2O2 system facilitates the assembly of bicyclic peroxides 337 The ability of heteropoly acids to form peroxo complexes and coordinate with the carbonyl group allows the peroxidation of ketones and their derivatives under milder conditions. For example, peroxidation of 1-aryl-2-allylalkane-1,3-diones 335 with I2/H2O2 system proceeds with the formation of iodinated ketoesters 336. The addition of catalytic The ability of heteropoly acids to form peroxo complexes and coordinate with the carbonyl group allows the peroxidation of ketones and their derivatives under milder conditions. For example, peroxidation of 1-aryl-2-allylalkane-1,3-diones 335 with I 2 /H 2 O 2 system proceeds with the formation of iodinated ketoesters 336. The addition of catalytic amounts of PMA to the I 2 /H 2 O 2 system facilitates the assembly of bicyclic peroxides 337 and 338 (Scheme 122) [220] . Ozonide 340 was obtained in one step by peroxidation of ketoacetal 339 with a yield of 74%. Phosphoromolybdic acid (PMA) was used as a catalyst in the amount of 0.02 equiv. with respect to 339. (Scheme 123) [218] . Phosphomolybdic (PMA) and phosphotungstic (PTA) acids efficiently catalyze the peroxidation reaction of β-diketones 341, including easily oxidized diketones, with the formation of bridged 1,2,4,5-tetraoxanes 342 (Scheme 124) [214] . Peroxides can be obtained in grams. The bridged 1,2,4,5-tetraoxane 342 containing an adamantane substituent in its composition exhibit a high activity (IC50: 0.3 μM) in vitro and in vivo (worm burden reduction was 75%) against S. mansoni [16] . Ozonide 340 was obtained in one step by peroxidation of ketoacetal 339 with a yield of 74%. Phosphoromolybdic acid (PMA) was used as a catalyst in the amount of 0.02 equiv. with respect to 339. (Scheme 123) [218] . Ozonide 340 was obtained in one step by peroxidation of ketoacetal 339 with of 74%. Phosphoromolybdic acid (PMA) was used as a catalyst in the amount equiv. with respect to 339. (Scheme 123) [218] . Phosphomolybdic (PMA) and phosphotungstic (PTA) acids efficiently catal peroxidation reaction of β-diketones 341, including easily oxidized diketones, w formation of bridged 1,2,4,5-tetraoxanes 342 (Scheme 124) [214] . Peroxides can be o in grams. The bridged 1,2,4,5-tetraoxane 342 containing an adamantane substitue composition exhibit a high activity (IC50: 0.3 μM) in vitro and in vivo (worm bur duction was 75%) against S. mansoni [16] . Phosphomolybdic (PMA) and phosphotungstic (PTA) acids efficiently catalyze the peroxidation reaction of β-diketones 341, including easily oxidized diketones, with the formation of bridged 1,2,4,5-tetraoxanes 342 (Scheme 124) [214] . Peroxides can be obtained in grams. The bridged 1,2,4,5-tetraoxane 342 containing an adamantane substituent in its composition exhibit a high activity (IC 50 : 0.3 µM) in vitro and in vivo (worm burden reduction was 75%) against S. mansoni [16] . The reaction of β,δ'-triketones 343, containing a benzyl substituent in the α-position, with an ethereal solution of H 2 O 2 , catalyzed by heteropoly acids (PMA, PTA) in a polar aprotic solvent, proceeds along three paths with the formation of three classes of peroxides: tricyclic monoperoxides 344, bridged tetraoxanes 345 and a pair of stereoisomeric ozonides 346 and 347 (Scheme 125) [215, 221] . The reaction is unusual in that bridged tetraoxanes and ozonides with a free carbonyl group were formed. The synthesis of ozonides from ketones and H 2 O 2 is a unique process in which ozonide is formed with the participation of two carbonyl groups. Bridged ozonides exhibit high in vitro cytotoxicity against androgen dependent prostate cancer cell lines DU145 and PC3. In some cases the anticancer activity of ozonides is higher than that of doxorubicin, cisplatin, and etoposide [222] . Phosphomolybdic (PMA) and phosphotungstic (PTA) acids efficiently catalyze the peroxidation reaction of β-diketones 341, including easily oxidized diketones, with the formation of bridged 1,2,4,5-tetraoxanes 342 (Scheme 124) [214] . Peroxides can be obtained in grams. The bridged 1,2,4,5-tetraoxane 342 containing an adamantane substituent in its composition exhibit a high activity (IC50: 0.3 μM) in vitro and in vivo (worm burden reduction was 75%) against S. mansoni [16] . The reaction of β,δ'-triketones 343, containing a benzyl substituent in the α-position, with an ethereal solution of H2O2, catalyzed by heteropoly acids (PMA, PTA) in a polar aprotic solvent, proceeds along three paths with the formation of three classes of peroxides: tricyclic monoperoxides 344, bridged tetraoxanes 345 and a pair of stereoisomeric ozonides 346 and 347 (Scheme 125) [215, 221] . The reaction is unusual in that bridged tetraoxanes and ozonides with a free carbonyl group were formed. The synthesis of ozonides from ketones and H2O2 is a unique process in which ozonide is formed with the participation of two carbonyl groups. Bridged ozonides exhibit high in vitro cytotoxicity against androgen dependent prostate cancer cell lines DU145 and PC3. In some cases the anticancer activity of ozonides is higher than that of doxorubicin, cisplatin, and etoposide [222] . More recently, an efficient catalyst H3+xPMo12-x 6+ Mox 5+ O40/SiO2 was developed for the synthesis of bridged ozonides 349, 350 and 1,2,4,5-tetraoxanes 352 under heterogeneous conditions (Scheme 126) [37] The synthesis of peroxides under heterogeneous conditions is a rare process and presents a challenge in this area of chemistry, as peroxides tend to decompose on the catalyst surface. The yield of diastereoisomeric bridged ozonides 349, 350 was up to 90%, and of bridged 1,2,4,5-tetraoxanes 352 wasup to 86%. More recently, an efficient catalyst H 3+x PMo 12-x 6+ Mo x 5+ O 40 /SiO 2 was developed for the synthesis of bridged ozonides 349, 350 and 1,2,4,5-tetraoxanes 352 under heterogeneous conditions (Scheme 126) [37] The synthesis of peroxides under heterogeneous conditions is a rare process and presents a challenge in this area of chemistry, as peroxides tend to decompose on the catalyst surface. The yield of diastereoisomeric bridged ozonides 349, 350 was up to 90%, and of bridged 1,2,4,5-tetraoxanes 352 wasup to 86%. The reaction of β,δ'-triketones 343, containing a benzyl substituent in the α-position, with an ethereal solution of H2O2, catalyzed by heteropoly acids (PMA, PTA) in a polar aprotic solvent, proceeds along three paths with the formation of three classes of peroxides: tricyclic monoperoxides 344, bridged tetraoxanes 345 and a pair of stereoisomeric ozonides 346 and 347 (Scheme 125) [215, 221] . The reaction is unusual in that bridged tetraoxanes and ozonides with a free carbonyl group were formed. The synthesis of ozonides from ketones and H2O2 is a unique process in which ozonide is formed with the participation of two carbonyl groups. Bridged ozonides exhibit high in vitro cytotoxicity against androgen dependent prostate cancer cell lines DU145 and PC3. In some cases the anticancer activity of ozonides is higher than that of doxorubicin, cisplatin, and etoposide [222] . More recently, an efficient catalyst H3+xPMo12-x 6+ Mox 5+ O40/SiO2 was developed for the synthesis of bridged ozonides 349, 350 and 1,2,4,5-tetraoxanes 352 under heterogeneous conditions (Scheme 126) [37] The synthesis of peroxides under heterogeneous conditions is a rare process and presents a challenge in this area of chemistry, as peroxides tend to decompose on the catalyst surface. The yield of diastereoisomeric bridged ozonides 349, 350 was up to 90%, and of bridged 1,2,4,5-tetraoxanes 352 wasup to 86%. This review summarizes approaches to the synthesis of organic peroxides under the action of Lewis acids and heteropoly acids. The possibility of Lewis acids to coordinate with the oxygen atom of the carbonyl group, as well as to generate a peroxycarbenium ion in the starting compounds, allows for the expansion of the potential of the peroxidation reaction of carbonyl compounds. The possibility of metal-containing compounds such as PMA, PTA, and MeReO 3 to form peroxo complexes with hydrogen peroxide makes it possible to transfer the peroxide function to the substrate. This transfer of peroxide groups, mediated by metal complexes, makes it possible to obtain organic peroxides under heterogeneous conditions. Analysis of the literature allows us to conclude that in the next decade the vector in peroxide chemistry will shift towards the use of the Lewis acid/peroxidizing agent system. This system is promising and its use will open up new horizons in peroxide chemistry for the chemical and medical industries. Handbook of Radical Polymerization Radical polymerization in industry Peroxide vulcanization of elastomers Hudec, I. Vulcanization of rubber compounds with peroxide curing systems Global Organic Peroxide Market Growth Qinghaosu (artemisinin): Chemistry and pharmacology Artemisinins: Pharmacological actions beyond anti-malarial Artemisinin: Discovery from the chinese herbal garden Study on the constituents of Artemisia-Annua L. 1. The isolation and identification of 11r-(-)-dihydroarteannuic acid Recent advances in antimalarial drug development Artemisinin): The price of success First assessment in humans of the safety, tolerability, pharmacokinetics, and ex vivo pharmacodynamic antimalarial activity of the new artemisinin derivative artemisone Artemisinin-derived dimers: Potent antimalarial and anticancer agents Artemisinin-derived dimers from a chemical perspective Dispiro-1,2,4,5-tetraoxanes-A new class of antimalarial peroxides Praziquantel analogs with activity against juvenile Schistosoma mansoni Elucidation of the in vitro and in vivo activities of bridged 1,2,4-trioxolanes, bridged 1,2,4,5-tetraoxanes, tricyclic monoperoxides, silyl peroxides, and hydroxylamine derivatives against Schistosoma mansoni Exogenous iron increases fasciocidal activity and hepatocellular toxicity of the synthetic endoperoxides OZ78 and MT04 Structure-activity relationship of antischistosomal ozonide carboxylic acids Tetraoxanes as antimalarials: Harnessing the endoperoxide Synthesis of spiro-bisperoxyketals Potent antimalarial 1,2,4-trioxanes through perhydrolysis of epoxides Synthetic peroxides as potent antimalarials. News and views Amino ozonides exhibit in vitro activity against Echinococcus multilocularis metacestodes Antimalarial peroxides Mixed steroidal 1,2,4,5-tetraoxanes: Antimalarial and antimycobacterial activity Peroxides with anthelmintic, antiprotozoal, fungicidal and antiviral bioactivity: Properties, synthesis and reactions Natural peroxy anticancer agents Bioactive peroxides as potential therapeutic agents Stable Tricyclic Antitubercular Ozonides Derived from Artemisinin Design, synthesis, and study of a mycobactin-artemisinin conjugate that has selective and potent activity against tuberculosis and malaria Design, synthesis, and biological evaluation of dihydroartemisinin-fluoroquinolone conjugates as a novel type of potential antitubercular agents Tetraoxanes as a new class of efficient herbicides comparable with commercial products Synthesis and biological evaluation of new ozonides with improved plant growth regulatory activity Synthesis and phytotoxic activity of ozonides Ion exchange resin-catalyzed synthesis of bridged tetraoxanes possessing in vitro cytotoxicity against HeLa cancer cells Cyclic synthetic peroxides inhibit growth of entomopathogenic fungus Ascosphaera apis without toxic effect on bumblebees Antifungal peroxide-containing acids from two Caribbean sponges New bioactive peroxides from marine sponges of the family Plakiniidae Recent advances in malaria drug discovery Comparative Antimalarial Activities and ADME Profiles of Ozonides (1,2,4-trioxolanes) OZ277, OZ439, and Their 1,2-Dioxolane, 1,2,4-Trioxane, and 1,2,4,5-Tetraoxane Isosteres Drug delivery to the malaria parasite using an Arterolane-like scaffold Peroxide antimalarial drugs target redox homeostasis in Plasmodium falciparum infected red blood cells. ACS Infect. Dis. 2022 Arterolane-piperaquine-mefloquine versus arterolane-piperaquine and artemether-lumefantrine in the treatment of uncomplicated Plasmodium falciparum malaria in Kenyan children: A single-centre, open-label, randomised, non-inferiority trial Antimalarial activity of artefenomel (OZ439), a novel synthetic antimalarial endoperoxide, in patients with Plasmodium falciparum and Plasmodium vivax malaria: An open-label phase 2 trial Inhibition of human coronaviruses by antimalarial peroxides Traditional Chinese Medicine in the Treatment of Patients Infected with 2019-New Coronavirus (SARS-CoV-2): A Review and Perspective In vitro efficacy of artemisinin-based treatments against SARS-CoV-2 Photochemical reactions in the interior of a zeolite. Part 5: The origin of the zeolite induced regioselectivity in the singlet oxygen ene reaction Regioselectivity in the ene reaction of singlet oxygen with alkenes Synthesis of antimalarial 1,2,4-trioxanes via photooxygenation of a chiral allylic alcohol Singlet oxygenation of 4-(4-tert-butyl-3,3-dimethyl-2,3-dihydrofuran-5-yl)-2-pyridone: Non-stereospecific 1,4-addition of singlet oxygen to a 1,3-diene system and thermal rearrangement of the resulting 1,4-endoperoxides to stable 1,2-dioxetanes The [4 + 2] addition of singlet oxygen to thebaine: New access to highly functionalized morphine derivatives via opioid endoperoxides Novel method for the preparation of triethylsilyl peroxides from olefins by the reaction with molecular-oxygen and triethylsilane catalyzed by bis(1,3-diketonato)Cobalt(II) An efficient method for the direct peroxygenation of various olefinic compounds with molecular-oxygen and triethylsilane catalyzed by a Cobalt(II) complex Co(III)-alkyl complex-and Co(III)-alkylperoxo complex-catalyzed triethylsilylperoxidation of alkenes with molecular oxygen and triethylsilane Co(thd)(2): A superior catalyst for aerobic epoxidation and hydroperoxysilylation of unactivated alkenes: Application to the synthesis of spiro-1,2,4-trioxanes Organocobalt complexes as sources of carbon-centered radicals for organic and polymer chemistries Synthesis of antimalarial yingzhaosu a analogues by the peroxidation of dienes with Co(II)/O 2 /Et 3 SiH Direct hydroperoxygenation of conjugated olefins catalyzed by cobalt(II) porphyrin Advances in the synthesis of acyclic peroxides Structure-activity relationship of anti-malarial spongean peroxides having a 3-methoxy-1,2-dioxane structure Facile construction of 6-carbomethoxymethyl-3-methoxy-1,2-dioxane, a core structure of spongean anti-malarial peroxides New readily accessible peroxides with high anti-malarial potency Stereoelectronic Interactions as a Probe for the Existence of the Intramolecular alpha-Effect Stereoelectronic power of oxygen in control of chemical reactivity: The anomeric effect is not alone Criegee intermediates beyond ozonolysis: Synthetic and mechanistic insights Mechanism of ozonolysis Ozonolyses of O-methyloximes in the presence of acid-derivatives-A new access to substituted ozonides Diozonides from coozonolyses of suitable O-methyl oximes and ketones The mechanism of ozonolysis revisited by O-17-NMR spectroscopy Differentiation between 1,2,4,5-tetraoxanes and 1,2,4,5,7,8-hexaoxonanes using H-1 and C-13 NMR analyses Intramolecular reactions of hydroperoxides and oxetanes: Stereoselective synthesis of 1,2-dioxolanes and 1,2-dioxanes How to Build Rigid Oxygen-Rich Tricyclic Heterocycles from Triketones and Hydrogen Peroxide: Control of Dynamic Covalent Chemistry with Inverse alpha-Effect Facile and selective procedure for the synthesis of bridged 1,2,4,5-tetraoxanes; strong acids as cosolvents and catalysts for addition of hydrogen peroxide to beta-diketones Identification of a 1,2,4,5-tetraoxane antimalarial drug-development candidate (RKA 182) with superior properties to the semisynthetic artemisinins Synthesis and antimalarial activity of sixteen dispiro-1,2,4,5-tetraoxanes: Alkyl-substituted 7,8 Antimalarial peroxides: The first intramolecular 1,2,4,5-tetraoxane Peroxides of higher aliphatic ethers Selective Synthesis of Cyclic Peroxides from Triketones and H 2 O 2 Synthesis of 1,2-dioxolanes by annulation reactions of peroxycarbenium ions with alkenes Synthesis of five-and six-membered cyclic organic peroxides: Key transformations into peroxide ring-retaining products Stereoelectronic Control in the Ozone-Free Synthesis of Ozonides Interrupted Baeyer-Villiger rearrangement: Building a stereoelectronic trap for the Criegee intermediate Boron Trifluoride as an Efficient Catalyst for the Selective Synthesis of Tricyclic Monoperoxides from beta,delta-Triketones and H 2 O 2 Peroxycarbenium-mediated C-C bond formation: Synthesis of cyclic peroxides from monoperoxyketals Selective synthesis of cyclic triperoxides from 1,1-dihydroperoxydi(cycloalkyl)peroxides and acetals using SnCl4 Synthesis of 1,1'-bishydroperoxydi(cycloalkyl) peroxides by homocoupling of 11-15-membered gem-bis (hydroperoxy)cycloalkanes in the presence of boron trifluoride The effect of iodine on the peroxidation of carbonyl compounds Stannous chloride dihydrate: A novel and efficient catalyst for the synthesis of gem-dihydroperoxides from ketones and aldehydes Lewis acid catalyzed nucleophilic ring opening and 1,3-bisfunctionalization of donor-acceptor cyclopropanes with hydroperoxides: Access to highly functionalized peroxy/(alphaheteroatom substituted)peroxy compounds Rearrangements of organic peroxides and related processes Selective transformation of tricyclic peroxides with pronounced antischistosomal activity into 2-hydroxy-1,5-diketones using iron (II) salts Migration aptitude as a criterion of ionic mechanism in the rearrangement of mono-pnitrotriphenylmethyl hydroperoxide Alkylhydroperoxyde aus alkylhalogeniden, II Tin chloride catalysed oxidation of acetone with hydrogen peroxide to tetrameric acetone peroxide Unexpected synthesis of (bis(diphenylphosphinoyl)ethane)center dot 2(2,2-dihydroperoxypropane) 1:2 adduct: A new route to stable organic dihydroperoxides Tin(IV) chloride promoted reaction of oxiranes with hydrogen peroxide Peroxycarbenium-mediated C-C bond formation: Synthesis of peroxides from monoperoxy ketals Hydroperoxide-mediated C-C bond formation: Synthesis of 1,2-dioxolanes from alkoxyhydroperoxides in the presence of Lewis-acids Peroxycarbenium-mediated C-C bond formation: Aplications to the synthesis of hydroperoxides and peroxides SnCl4-mediated reaction of ozonides with allyltrimethylsilane: Formation of 1,2-dioxolanes Selectivity in Lewis acid-mediated fragmentations of peroxides and ozonides: Application to the synthesis of alkenes, homoallyl ethers, and 1,2-dioxolanes Synthesis of 3,5-disubstituted 1,2-dioxolanes through the use of acetoxy peroxyacetals Spiro-and dispiro-1,2-dioxolanes: Contribution of iron(II)-mediated one-electron vs. two-electron reduction to the activity of antimalarial peroxides Synthesis of Silyl Monoperoxyketals by Regioselective Cobalt-Catalyzed Peroxidation of Silyl Enol Ethers: Application to the Synthesis of 1,2-Dioxolanes Synthesis of spiro-1,2-dioxolanes and their activity against Plasmodium falciparum Structure-activity relationship of an ozonide carboxylic acid (OZ78) against Fasciola hepatica Reaction of peroxyacetals with silyl ketene acetals: Synthesis of 3-peroxyalkanoates and 3-peroxyalkanals Asymmetric synthesis of 1,2-dioxolane-3-acetic acids: Synthesis and configurational assignment of plakinic acid A Stereocontrolled formation of epoxy peroxide functionality appended to a lactam ring Trans-3,5-dihydroperoxy-3,5-dimethyl-1,2-dioxolane as a novel and efficient reagent for selective sulfoxidation of sulfides under catalyst-free condition AlCl 3 .6H 2 O as a catalyst for simple and efficient synthesis of gem-dihydroperoxides from ketones and aldehydes using aqueous H 2 O 2 Energetic materials trends in 5-and 6-membered cyclic peroxides containing hydroperoxy and hydroxy substituents Peroxo complexes of molybdenum, tungsten and rhenium with phase transfer active ligands: Catalysts for the oxidation of olefins and aromatics by hydrogen peroxide and bistrimethylsilyl peroxide Thermodynamic studies of the binding of bidentate nitrogen donors with methyltrioxorhenium (MTO) in CHCl 3 solution Water-catalyzed activation of H 2 O 2 by methyltrioxorhenium: A combined computational-experimental study Synthesis and antimalarial activities of novel 3,3,6,6-tetraalkyl-1,2,4,5-tetraoxanes Synthesis, thermal stability, antimalarial activity of symmetrically and asymmetrically substituted tetraoxanes Synthesis and in vitro antimalarial activity of tetraoxaneamine/amide conjugates One-pot synthesis of non-symmetric tetraoxanes with the H 2 O 2 /MTO/fluorous alcohol system Two-step synthesis of achiral dispiro-1,2,4,5-tetraoxanes with outstanding antimalarial activity, low toxicity, and high-stability profiles Synthesis and in vitro antimalarial activity of several simple analogues of peroxyplakoric acid Simplified analogues of qinghaosu (artemisinin) An approach to alpha-and beta-amino peroxides via lewis acid catalyzed ring opening-peroxidation of donor-acceptor aziridines and n-activated aziridines Opening of substituted oxetanes with H 2 O 2 and alkyl hydroperoxides: Stereoselective approach to 3-peroxyalcohols and 1,2,4-trioxepanes Anti-protozoal and anti-fungal evaluation of 3,5-disubstituted 1,2-dioxolanes Access to functionalized 3,5-disubstituted 1,2-dioxolanes under mild conditions through indium(III) chloride/trimethylsilyl chloride or scandium(III) triflate catalysis Spirofused and annulated 1,2,4-trioxepane-, 1,2,4-trioxocane-, and 1,2,4-trioxonane-cyclohexadienones: Cyclic peroxides with unusual ring conformation dynamics Oxymetallation. Part VI. Halogenodemercuration of peroxymercurials derived from αβunsaturated esters and ketones Part 17. t-Butyl peroxymercuriation and subsequent demercuriation of phenylcyclopropane Peroxymercuration of dienes-simple route to new cyclic peroxides Regioselective synthesis of isomeric bicyclic peroxides Part 11. Synthesis of cyclic secondary alkyl peroxides via peroxymercuration of alpha,omega-dienes Cyclic peroxides by intra-molecular peroxymercuration of unsaturated hydroperoxides Hydroperoxymercuriation using 30% hydrogen peroxide Synthesis of alkyl hydroperoxides by hydroperoxymercuriation and reduction Mercury(II)-mediated cyclization of hydroperoxyalkylcyclopropanes-A new route to cyclic peroxides A short synthesis of naturally occurring and other analogues of plakinic acids that contain the 1,2-dioxolane group Efficient conversion of epoxides into beta-hydroperoxy alcohols catalyzed by antimony trichloride/SiO 2 Mild and efficient strontium chloride hexahydrate-catalyzed conversion of ketones and aldehydes into corresponding gem-dihydroperoxides by aqueous H 2 O 2 A simple and efficient synthesis of gem-dihydroperoxides from ketones using aqueous hydrogen peroxide and catalytic ceric ammonium nitrate A facile and efficient Bi(III) catalyzed synthesis of 1,1-dihydroperoxides and 1,2,4,5-tetraoxanes The activity of dispiro peroxides against Fasciola hepatica Formation of 3,6-dialkyl-1,2,4,5-tetraoxans and related cyclic bis-(peroxides) by the action of antimony pentachloride or chlorosulfonic acid on ozonides Palladium(II)-catalyzed cyclization of unsaturated hydroperoxides for the synthesis of 1,2-dioxanes Preparation of Organic Hydroperoxides Organic peroxides. Part I. The preparation of alkyl hydroperoxides from hydrogen peroxide The 'super acid' BF 3 . H 2 O stabilized by 1,4-dioxane: New preparative aspects and the crystal structure of BH 3 H 2 O . C 4 H 8 O 2 Superacid BF 3 -H 2 O promoted benzylation of arenes with benzyl alcohols and acetates initiated by trace water Fluoroanalogs of DDT: Superacidic BF 3 -H 2 O catalyzed facile synthesis of 1,1,1-trifluoro-2,2-diarylethanes and 1,1-difluoro-2,2-diarylethanes N-Halosuccinimide/BF 3 -H 2 O, efficient electrophilic halogenating systems for aromatics BF 3 -H 2 O catalyzed hydroxyalkylation of aromatics with aromatic aldehydes and dicarboxaldehydes: Efficient synthesis of triarylmethanes, diarylmethylbenzaldehydes, and anthracene derivatives Highly effective catalysts for the addition polymerization of norbornene: Zerovalent-nickel complex/H 2 O/BF 3 . OEt 2 Production of Per-Fatty Acids. US2806045A Novel synthesis of asymmetric alkyl peroxides using tertiary alcohols A new method for the synthesis of bishydroperoxides based on a reaction of ketals with hydrogen peroxide catalyzed by boron trifluoride complexes Synthesis of peroxide compounds by the BF 3 -catalyzed reaction of acetals and enol ethers with H 2 O 2 Synthesis of geminal bisperoxides by acid-catalyzed reaction of acetals and enol ethers with tert-butyl hydroperoxide Synthesis of a nitro analogue of plakoric acid Synthesis of a 1,2,7,8-tetraoxa-spiro [5.5]undecane A family of new 1,2,4-trioxanes by photooxygenation of allylic alcohols in sensitizer-doped polymers and secondary reactions Novel spiroanellated 1,2,4-trioxanes with high in vitro antimalarial activities ]hexadecanes: Novel spirofused bis-trioxane peroxides Singlet oxygen addition to chiral allylic alcohols and subsequent peroxyacetalization with beta-naphthaldehyde: Synthesis of diastereomerically pure 3-beta-naphthyl-substituted 1,2,4-trioxanes Synthesis and decomposition of E-and Z-3,3,5-trisubstituted 1,2-dioxolanes New preparation of 1,2,4,5-tetraoxanes Synthesis and antimalarial activity of new 1,2,4,5-tetroxanes and novel alkoxy-substituted 1,2,4,5-tetroxanes derived from primary gem-dihydroperoxides Antitumoractive endoperoxides from triterpenes New preparation of 1,2,4,5,7,8-hexaoxonanes Bicyclic peroxides and perorthoesters with 1,2,4-trioxane structures Ozone-Free Synthesis of Ozonides: Assembling Bicyclic Structures from 1,5-Diketones and Hydrogen Peroxide Synthetic peroxides promote apoptosis of cancer cells by inhibiting p-glycoprotein ABCB5 Five roads that converge at the cyclic peroxy-criegee intermediates: BF 3 -catalyzed synthesis of beta-hydroperoxy-beta-peroxylactones Peroxycarbenium Ions as the "Gatekeepers" in Reaction Design: Assistance from Inverse Alpha-Effect in Three-Component beta-Alkoxy-beta-peroxylactones Synthesis Synthesis of unstrained Criegee intermediates: Inverse alpha-effect and other protective stereoelectronic forces can stop Baeyer-Villiger rearrangement of gamma-hydroperoxy-gamma-peroxylactones Total Synthesis of Verruculogen and Fumitremorgin A Enabled by Ligand-Controlled C-H Borylation Halogen bonding in organic synthesis and organocatalysis The halogen bond The halogen bond with isocyano carbon reduces isocyanide odor Halogen-bonded iodonium ion catalysis: A route to alpha-hydroxy ketones via domino oxidations of secondary alcohols and aliphatic C-H bonds with high selectivity and control Activation of a carbonyl compound by halogen bonding Halogen bond-catalyzed friedel-crafts reactions of aldehydes and ketones using a bidentate halogen bond donor catalyst: Synthesis of symmetrical bis(indolyl)methanes Mechanisms in iodine catalysis A new approach to the synthesis of vicinal iodoperoxyalkanes by the reaction of alkenes with iodine and hydroperoxides Synthesis of 1,2-dioxanes, 1,2,4-trioxanes, and 1,2,4-trioxepanes via cyclizations of unsaturated hydroperoxyacetals Synthesis and antimicrobial activity of geminal bis-hydroperoxides Reaction of enol ethers with the I 2 -H 2 O 2 system: Synthesis of 2-iodo-1-methoxy hydroperoxides and their deperoxidation and demethoxylation to 2-iodo ketones Reactions of mono-and bicyclic enol ethers with the I 2 -hydroperoxide system Synthesis of 1-hydroperoxy-1'-alkoxyperoxides by the iodine-catalyzed reactions of geminal bishydroperoxides with acetals or enol ethers Transformation of 2-allyl-1,3-diketones to bicyclic compounds containing 1,2-dioxolane and tetrahydrofuran rings using the I-2/H2O2 system Synthesis of 1,2,4,5,7,8-hexaoxonanes by iodine-catalyzed reactions of bis(1-hydroperoxycycloalkyl) peroxides with ketals Efficient preparation of 1,2,4,5-tetroxanes from bis(trimethylsilyl) peroxide and carbonylcompounds Synthesis, crystal structure and antimalarial activity of novel 1,2,5,6-tetraoxacycloalkanes from 2,3-dihydroperoxy-2-phenylnorbornane Cholic acid derivatives as 1,2,4,5-tetraoxane carriers: Structure and antimalarial and antiproliferative activity Antimalarial activity of novel 1,2,5,6-tetraoxacycloalkanes and 1,2,5-trioxacycloalkanes The reaction of trimethylsilyl alpha-trimethylsilylperoxy esters with ketones and aldehydes-A simple, efficient synthesis of 1,2,4-trioxan-5-one The synthesis of 1,2,4-trioxan-5-ones Reactions of cyclic peroxides with aldehydes and ketones catalyzed by trimethylsilyl trifluoromethanesulfonate-An efficient synthesis of 1,2,4-trioxanes Synthesis, structure, and antimalarial activity of some enantiomerically pure, cis-fused cyclopenteno-1,2,4-trioxanes Synthesis and stereochemical study of a trioxaquine prepared from cis-bicyclo Synthesis and antimalarial activity of trioxaquine derivatives New methods for the synthesis of oxy-functionalized 1,2,4-trioxanes and 1,2,4-trioxepanes from unsaturated hydroperoxy acetals Synthesis of 1,2-dioxanes from an endoperoxide Lewis acid catalysed rearrangements of unsaturated bicyclic [2.2.n] endoperoxides in the presence of vinyl silanes; access to novel Fenozan BO-7 analogues Synthesis of 3-hydroperoxy (or hydroxy)substituted 1,2-dioxanes and 1,2-dioxepanes by the ozonolysis of unsaturated hydroperoxy acetals Olefin oxidative cleavage and dioxetane formation using triethylsilyl hydrotrioxide-Applications to preparation of potent antimalarial 1,2,4-trioxanes Extraordinarily potent antimalarial compounds-New, structurally simple, easily synthesized, tricyclic 1,2,4-trioxanes Synthesis and antimalarial activities of structurally simplified 1,2,4-trioxanes related to Artemisinin A short synthesis of antimalarial peroxides Phosphomolybdic and phosphotungstic acids as efficient catalysts for the synthesis of bridged 1,2,4,5-tetraoxanes from β-diketones and hydrogen peroxide Approach for the preparation of various classes of peroxides based on the reaction of triketones with H 2 O 2 : First examples of ozonide rearrangements Heteropoly acid/NaY zeolite as a reusable solid catalyst for highly efficient synthesis of gem-dihydroperoxides and 1,2,4,5-tetraoxanes Catalytic condensation process for the preparation of organic peroxides from tert-butyl hydroperoxide and benzylic alcohols A broadly applicable mild method for the synthesis of gem-diperoxides from corresponding ketones or 1,3-dioxolanes Facile perhydrolysis of oxetanes catalyzed by molybdenum species Convenient synthesis of furo Synthesis of peroxides from beta,delta-triketones under heterogeneous conditions Cyclic peroxides as promising anticancer agents: In vitro cytotoxicity study of synthetic ozonides and tetraoxanes on human prostate cancer cell lines Institutional Review Board Statement: Not applicable. Data Availability Statement: Not applicable. The authors declare that they have no conflict of interest.