1. Introduction

Since the first synthesis of 3-amino-2H-azirines (Rens & Ghosez, 1970), the chemistry of these three-membered cyclic amidines has been studied intensively (Heimgartner, 1979, 1981, 1986, 1991; Eremeev & Piskunova, 1990). They have been found to be versatile building blocks in heterocyclic and peptide synthesis. In com­parison with the better known 3-aryl-2H-azirines (three-mem­bered cyclic imines), the 3-amino derivatives are stronger bases and more reactive nucleophiles. For example, 3-phenyl-2H-azirine reacts with carb­oxy­lic acids in refluxing benzene to give the corresponding N-phenacyl­car­box­amides (Sato et al., 1967; Black & Doyle, 1978), and the reaction of 2,2-dimethyl-3-phenyl-2H-azirine with mercapto­acetic acid was performed in acetone at 343 K for 15 h yielding N-(1,1-dimethyl-2-oxo-2-phenyl­eth­yl)-2-mercaptoacetamide (Él'kinson & Eremeev, 1986). Only 3-alkyl-2H-azirine-2-phos­phine oxides exhibited a higher reactivity; a slow reaction with carb­oxy­lic acids in tetra­hydro­furan (THF) occurs already at room temperature within 1–4 days (Palacios et al., 2002). On the other hand, N,N-disubstituted 3-amino-2H-azirines of type 1 react with carb­oxy­lic acids (Vittorelli et al., 1974; Obrecht & Heimgartner, 1983) and N-protected amino acids (Obrecht & Heimgartner, 1987; Wipf & Heimgartner, 1988; Dan­necker-Dörig et al., 2011) at 273–298 K within a few minutes to give products of type 2 (Scheme 1). The analogous reaction of 3-amino-2-phenyl­carbamoyl-2H-azirine with acetic acid in ace­tone was carried out at 323 K within 1 h (Eremeev et al., 1985).

Furthermore, 3-amino-2H-azirines, 1, react spontaneously with NH-acidic heterocycles if their pK_a value is less than 8 (Chaloupka et al., 1977; Scholl et al., 1978). For example, the reaction with 3,3-disubstituted azetidine-2,4-diones (malon­imides) in 2-propanol at room temperature yields 1,4-diazepine derivatives, 3 (Scheme 1). In all of these reactions, 1 has to be activated by protonation to enable the addition of the nucleophilic com­pound. On the other hand, reactions of 1 with non-acidic N-nucleophiles, such as primary amino com­pounds (Hugener & Heimgartner, 1995) or sodium amidates (Arnhold et al., 1995), can be performed via BF₃ catalysis. In the latter case, 4,4-di­substituted 5-amino-4H-imidazoles, 4, are formed (Scheme 1); the reaction mechanism is explained by the initial com­plexation of the ring N atom of 1 with BF₃. Similarly, the ZnCl₂-catalyzed reaction of 3-aryl-2H-azirines with benzimidates has been elaborated as an efficient preparation of imidazoles (Shi et al., 2018).

Based on these results, we expected that reactions of 1 with nucleophiles may also be catalyzed by com­plexation of 1 with ZnBr₂ or PdCl₂. Corresponding com­plexes of 3-amino-2H-azirines 1 are known (Hassner et al., 1978; Dietliker et al., 1978; Dos Santos Filho et al., 1983; Heimgartner, 1991; Villalgordo & Heimgartner, 1993). Unfortunately, attempts to catalyze the reaction of 1a with imidazolidine-2,4-diones (hydantoins), 5, by using ZnBr₂ (Scheme 2) were only mildly successful (Schläpfer-Dähler et al., 1992). Whereas the formation of the 4H-imidazole derivatives, 6, from 1a and 5 was achieved in refluxing aceto­nitrile within two days, the reaction of the azirine com­plex 7 with 5 was com­plete after 14–24 h, and after decom­plexation of the 4H-imidazole com­plexes, 8, by treatment with NaOH, com­pounds 6 were obtained in slightly increased yields.

On the other hand, we successfully used the com­plexation of the hetero­spiro­cyclic 3-amino-2H-azirine, 9, with PdCl₂ for the chromatographic purification of this com­pound as a race­mate (Villalgordo & Heimgartner, 1993). Because 3-am­ino-2H-azirines with two different substituents at the alkyl atom, C2, of the azirine ring, e.g. 10–12, are useful building blocks for chiral α,α-disubstituted α-amino acids, the separation of the diastereoisomers or enanti­omers is an important issue (Bucher et al., 1995, 1996, 2020; Brun et al., 2001, 2002). Therefore, we synthesized the azirines 10–12 with the aim of separating the stereoisomers after their direct crystallization or crystallization of their PdCl₂ com­plexes (Scheme 3).

2. Experimental

2.1. Synthesis and crystallization

The 3-amino-2H-azirines 10–12 were prepared according to previously described syntheses. In the case of 10, sequential treatment of 1 g (3.19 mmol) of a diastereomeric mixture of the corresponding 2-methyl­butyric acid amide, 13, bearing the chiral residue derived from (−)-trans-myrtanol, in dry THF (15 ml) with lithium diiso­propyl­amide (LDA), di­phenyl­phosphoryl chloride (DPPCl) and NaN₃ in DMF (Scheme 4; Villalgordo, 1992; cf. Villalgordo & Heimgartner, 1993) led to the desired product. Chromatographic work-up on SiO₂ (hex­ane–AcOEt, 9:1 v/v) gave 712 mg (72%) of 10 as a mix­ture of diastereoisomers as a slightly yellow oil. To a well-stirred suspension of 156 mg (0.654 mmol) PdCl₂ in dry aceto­nitrile (MeCN, 1.5 ml) at 273 K was added a solution of 200 mg (0.654 mmol) of azirine 10 in MeCN (0.5 ml). After stirring for 10 h, the solvent was partially evaporated and the residue was filtered through a short column of SiO₂ (hexa­ne–ethyl acetate, 9:1 v/v). Evaporation of the solvents gave 475 mg (92%) of the Pd com­plex, 14, as a red–orange solid. Recrystallization from MeCN by slow evaporation of the

solvent yielded orange crystals of suitable quality for crystal structure analysis. The crystal structure of 14 revealed that one of each of the diastereoisomers of 10 were coordinated to the Pd centre to give a mol­ecule with the absolute stereochemistry shown in Scheme 4.

Starting with the known (S)-pyrrolidine derivative 15 (Enders et al., 1988), the azirine 17 was prepared following pro­cedures described earlier (Scheme 5; Bucher, 1996; cf. Bucher & Heimgartner, 1996). Whereas the precursor 16 was obtained in good yield (84%) as a mixture of diastereoisomers, the standard transformation to the amino­azirine led to a ca 2:1 mixture of the diastereomeric azirines 17 in only 10% yield. The electrolytical removal of the phenyl­sulfonyl group (–2.1 V, EtOH, Me₄NCl, 278 K; cf. Bucher & Heimgartner, 1996) gave only a few crystals of the desired azirine 11, which were recrystallized from MeOH/Et₂O, yielding crystals suitable for crystal structure determination.

3-Amino-2-benzyl-2-phenyl-2H-azirine 12 was synthesized either from the amide 18 (cf. Villalgordo & Heimgartner, 1993) or the thio­amide 19 (cf. Bucher et al., 1995; Brun et al., 2002), respectively (Scheme 6). In the first case, starting with 2.50 g (7.9 mmol) of 18, azirine 12 was obtained in 70% yield (1.74 g) as a slightly yellow oil, which solidified under high vacuum (Gubler, 1996). In the second approach, the amide 18 was transformed into the thio­amide 19 in 94% yield, and 19.20 g (57.9 mmol) of the latter were treated with phosgene in DMF/CH₂Cl₂ and then with sodium azide in THF/DMF to give 11.05 g (61%) of azirine 12 as a yellowish solid. Recrystallization of the azirine 12 from Et₂O/hexane yielded colourless crystals of a single enanti­omer suitable for a crystal structure analysis.

2.3. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 1. For each structure, the methyl H atoms were constrained to an ideal geometry (C—H = 0.98 Å), with U_iso(H) = 1.5U_eq(C), but were allowed to rotate freely about the C—C bonds. All other H atoms were placed in geometrically idealized positions and constrained to ride on their parent atoms with C—H distances of 0.95 (aromatic), 0.99 (methyl­ene) or 1.00 Å (methine) and with U_iso(H) = 1.2U_eq(C).

Table 1 Experimental details Experiments were carried out at 173 K with Mo Kα radiation using a Rigaku AFC-5R diffractometer. H-atom parameters were constrained.   11 12 14 Crystal data Chemical formula C23H28N2O C22H20N2 [PdCl2(C21H30N2)2] Mr 348.47 312.40 798.24 Crystal system, space group Monoclinic, P21 Orthorhombic, P212121 Triclinic, P1 a, b, c (Å) 7.792 (4), 14.462 (6), 9.113 (3) 10.642 (2), 15.8762 (18), 10.273 (2) 9.070 (2), 10.504 (6), 11.756 (2) α, β, γ (°) 90, 105.87 (3), 90 90, 90, 90 80.14 (3), 76.054 (19), 73.67 (2) V (Å3) 987.8 (8) 1735.7 (5) 1036.7 (7) Z 2 4 1 μ (mm−1) 0.07 0.07 0.61 Crystal size (mm) 0.38 × 0.23 × 0.23 0.48 × 0.40 × 0.35 0.48 × 0.25 × 0.25   Data collection No. of measured, independent and observed [I > 2σ(I)] reflections 3163, 2962, 1920 3349, 3238, 2569 6352, 6046, 5673 Rint 0.029 0.014 0.015 (sin θ/λ)max (Å−1) 0.703 0.703 0.704   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.058, 0.157, 1.02 0.043, 0.118, 1.04 0.033, 0.087, 1.06 No. of reflections 2962 3238 6046 No. of parameters 345 218 600 No. of restraints 398 0 629 Δρmax, Δρmin (e Å−3) 0.29, −0.27 0.22, −0.18 0.73, −0.34 Absolute structure Absolute structure set to match the known S-con­figuration at atom C9 of the pyrrolidine residue Absolute structure chosen arbitrarily Flack parameter determined by classical intensity fit (Flack & Bernardinelli, 1999, 2000) Absolute structure parameter −1 (3) −1.8 (10) −0.02 (2) Computer programs: MSC/AFC Diffractometer Control Software (Molecular Structure Corporation, 1991), TEXSAN PROCESS (Molecular Structure Corporation, 1989), SHELXT2018 (Sheldrick, 2015a), SHELXL2019 (Sheldrick, 2015b), OLEX2 (Dolomanov et al., 2009), publCIF (Westrip, 2010) and PLATON (Spek, 2020).

The mol­ecule in the crystal structure of com­pound 11 is disordered in two regions. Atom C7 of the five-membered ring occupies two positions which represent alternate envelope conformations of the ring; the site-occupation factor of the major conformer refined to 0.619 (18). In addition, the azirine ring and its C2-ethyl and methyl substituents required three sets of positions to adequately model the arrangement. These positions indicate that the 2R and 2S diastereoisomers have crystallized at the same crystallographic site in the crystal and that the 2S diastereoisomer is further disordered over two conformations. The site occupation of the 2R con­figuration at atom C2 refined to 0.432 (3), while the site-occupation factors for the two conformations of the 2S diastereoisomer refined to 0.305 (3) and 0.263 (3) for the conformations containing atoms with A and B suffixes, respectively, in their labels (Fig. 1). Target bond-length restraints were applied to the disordered atoms. In addition, similarity restraints were applied to the chemically equivalent bond lengths and angles involving all disordered atoms, while neighbouring atoms within and between each arrangement of the disordered groups were restrained to have similar atomic displacement parameters.

Figure 1 Views and atom-labelling schemes of the individual disordered com­ponents in the mol­ecular structure of 11, showing (a) the disorder com­ponent com­posed of the 2R diastereoisomer, and (b) the major and (c) the minor disordered conformations in the com­ponent com­posed of the 2S diastereo­isomer. Displacement ellipsoids are drawn at the 50% probability level. H atoms have been omitted for clarity. An overlay of all three disorder com­ponents is presented in the supporting information (Fig. S1).

In the structure of 14, the chiral residue derived from (−)-trans-myrtanol in each ligand is conformationally disordered. Two sets of positions were defined for the atoms of each disordered residue and the site-occupation factors of the major conformations of these groups refined to 0.621 (11) and 0.675 (9) for the ligands containing atoms N1 and N21, respectively. Similarity restraints were applied to the chemically equivalent bond lengths involving all disordered C atoms, while neighbouring atoms within and between each conformation of the disordered groups were restrained to have similar atomic displacement parameters.

3. Results and discussion

The syntheses described in the Introduction include nonstereo­specific reactions during the azirine ring formation to give 3-amino-2H-azirines. Therefore, the products are expected to be either racemic mixtures or, when another residue in the mol­ecule contains one or more invariant stereogenic centres, mixtures of diastereoisomers. The three crystal structures described here are of crystals obtained from the products 11 (Fig. 1), 12 (Fig. 2) and the PdCl₂ com­plex with 10 (14; Fig. 3). The chosen crystal in each case had crystallized in a chiral space group, which is a necessity for 11 and 14, because these mol­ecules contain invariant chiral exocyclic amine residues derived from the known (S)-pyrrolidine derivative, 15, and (−)-trans-myrtanol {i.e. [(1S,2S,5S)-6,6-di­methylbi­cyclo­[3.1.1]heptan-2-yl]methanol}, respectively. The absolute structure chosen when refining the models for 11 and 14 was thus aligned to match the chirality of the known chiral residues. In the case of 14, the strong anomalous scattering power im­parted by the Pd and Cl atoms allowed the absolute con­fig­uration of all stereogenic centres to be confirmed confidently from the diffraction experiment by refinement of the absolute structure parameter (Flack & Bernardinelli, 1999, 2000), which converged to a value of −0.02 (2). The absolute structure of 11 could not be determined independently from the diffraction experiment on account of the weak anomalous scattering power of the com­pound with the available Mo Kα X-ray radiation (the work was carried out in the early 1990s when it was not common to use Cu Kα radiation routinely).

Figure 2 View of the mol­ecule of 12, showing the atom-labelling scheme. Displacement ellipsoids are drawn at the 50% probability level. H atoms are represented by circles of arbitrary size.

Figure 3 Views of the (a) major and (b) minor disorder com­ponents of the mol­ecule of 14, showing the atom-labelling schemes. Displacement ellipsoids are drawn at the 50% probability level. H atoms have been omitted for clarity. An overlay of the two disorder com­ponents is presented in the supporting information (Fig. S2).

In contrast, com­pound 12 only contains a single stereogenic centre, which is at atom C2 of the azirine ring, so a racemic mixture could conceivably have crystallized in an achiral space group. Given that the synthesis of com­pound 12 most likely produced a racemic mixture of the product and not a single enanti­omer, the fact that com­pound 12 crystallized in a chiral space group indicates that either a single enanti­omer has crystallized in a spontaneous resolution process, or the crystal is an inversion twin and therefore a racemic mixture or another ratio (solid solution) of enanti­omers. For the same reasons as given above for com­pound 11, the absolute structure of 12 could not be determined. Therefore, the presence of a specific enanti­omer or even an inversion twin could not be established and the con­figuration of the mol­ecule defined in the refinement model and depicted in Fig. 2 was chosen arbitrarily.

The unique mol­ecule in the crystal structure of com­pound 11 is disordered in two regions (Fig. 1). The five-membered pyrrolidine ring has two distorted envelope conformations, while the azirine ring and its C2-ethyl and methyl substituents are disordered over three arrangements. The disorder model indicates that the 2R and 2S diastereoisomers are present in the crystal and are distributed randomly at the same crystallographic site. There is a slight excess of the 2S diastereo­isomer, which is disordered additionally over two con­form­ations (see Section 2.3 for more details).

The crystal structure of com­pound 14 reveals one symmetry-unique trans-PdCl₂L¹L² com­plex mol­ecule, where L¹ and L² are diastereoisomers of product 10, which coordinate to the metal via their azirine ring N atom (Fig. 3). The diastereoisomers are the 2S and 2R species which result from inter­change of the positions of the ethyl and methyl substituents at atom C2 of the azirine ring, while the con­figuration of the chiral residue derived from (−)-trans-myrtanol remains con­stant. It is perhaps remarkable that the Pd com­plex con­tains one of each of the pair of diastereoisomers, as conceivably the com­plex could consist of two of the same di­as­tereo­isomer or a nonstoichiometric ratio of the two diastereoisomers, which would manifest itself in the same sort of disorder of the ethyl and methyl substitution site that was observed for 11, as described above. In the structure of 14, the chiral residue derived from (−)-trans-myrtanol in each ligand is conformationally disordered (Fig. 3), but this has no consequence for the unique absolute con­figuration of the residue. The coordination geometry around the Pd atom is square planar, as usual, and the coordination geometry is listed in Table 2.

Reports of crystal structures of 3-amino-2H-azirines are quite rare. The Cambridge Structural Database (CSD; Version 5.43 with November 2022 updates; Groom et al., 2016) lists only 11 structures, of which seven have been reported by the Heimgartner group (Villalgordo & Heimgartner, 1992; Bucher & Heimgartner, 1996; Brun et al., 2001) and the remaining four were reported by Galloy et al. (1974, 1980), Piskunova et al. (1993) and Peters et al. (2000). The geometry of the azirine ring (Table 3) generally shows little variation across all of these structures. Possibly the most remarkable feature is the very long N—C single bond, which is, with one exception, always around 1.57 Å [mean 1.572 (5) Å for 10 structures], com­pared with N—C distances closer to 1.47 Å usually found for simple imines. This contrasts with the shorter formal C—C single bond with a mean length of 1.437 (7) Å. The short formal C—N single bond to the exocyclic N atom, with a mean value of 1.333 (12) Å, is likely a consequence of electron-pair delocalization between the exocyclic N atom and the ring N=C bond; Galloy et al. (1974) described this as the consequence of a contribution from a polar mesomeric form. The biggest ring geometry outlier amongst the 11 structures men­tioned above is in the structure of 3-di­methyl­amino-2-di­methyl­carbamoyl-2-phen­oxy-2H-azirine (3-phen­oxy-3-di­methyl­carbamoyldi­methyl­amino-2-azirine) (Galloy et al., 1974), in which, in particular, the ring N—C single bond of 1.49 Å is significantly shorter than in the other structures. This might result from the inductive electron-withdrawal properties of the O atom in the phenoxy substituent at the azirine ring sp³-hybridized C atom, whereas all other structures have C atoms as the first atom of each substituent. The three new crystal structures reported here are no exception, notwithstanding the potential low accuracy for the disordered azirine ring in 11 because of the restraints applied while modelling the disorder; see Section 2.3. The coordination of the azirine rings via their N atom to the Pd atom in com­plex 14 also appears to influence very slightly the geometry of the azirine ring to give marginally shorter N—C and longer C—C single bonds, respectively (Table 3). This is perhaps unsurprising given the change in the electronic properties as a result of the coordination.

Table 3 Azirine ring geometry (Å, °) in 3-amino-2H-azirines CSD refcode/Compound No. N1=C3 N1—C2 C2—C3 C3—N4 C3=N1—C2 N1=C3—C2 N1—C2—C3 Reference ABUKUD 1.271 (3) 1.577 (3) 1.436 (3) 1.333 (3) 59.38 (16) 71.01 (19) 49.61 (15) Brun et al. (2001) ABULAK 1.275 (5) 1.577 (5) 1.436 (5) 1.347 (4) 59.4 (2) 70.9 (3) 49.8 (2) Brun et al. (2001) ABULEO 1.2712 (13) 1.5766 (16) 1.4290 (16) 1.3401 (12) 59.08 (7) 71.178 (7) 49.74 (7) Brun et al. (2001) ABULIS 1.277 (3) 1.570 (3) 1.435 (3) 1.340 (2) 59.49 (14) 70.47 (14) 50.05 (12) Brun et al. (2001) ABULOY 1.290 (8) 1.575 (7) 1.442 (10) 1.327 (9) 59.5 (4) 70.1 (5) 50.4 (4) Brun et al. (2001) HAGGUR 1.262 1.565 1.454 1.317 60.8 69.9 49.3 Piskunova et al. (1993) JUNJEH 1.264 (3) 1.565 (3) 1.434 (3) 1.342 (3) 59.8 (2) 70.6 (2) 49.6 (1) Villalgordo & Heimgartner (1992) LERJUN 1.278 (3) 1.568 (3) 1.435 (4) 1.315 (4) 59.55 (18) 70.3 (2) 50.17 (16) Peters et al. (2000) MAZRPZ 1.254 1.575 1.428 1.343 59.4 71.6 49.1 Galloy et al. (1980) PXCAZN 1.279 1.490 1.429 1.317 61.6 66.5 51.9 Galloy et al. (1974) TIBFUF 1.283 (3) 1.568 (3) 1.438 (3) 1.322 (3) 59.56 (16) 70.12 (16) 50.32 (14) Bucher & Heimgartner (1996) 11, 2R com­ponent 1.280 (6) 1.525 (6) 1.456 (6) 1.323 (5) 61.8 (3) 67.4 (4) 50.8 (3) This work 11, 2S major com­ponent 1.281 (6) 1.515 (7) 1.448 (6) 1.323 (5) 61.7 (4) 67.1 (4) 51.1 (3) This work 11, 2S minor com­ponent 1.283 (7) 1.517 (7) 1.475 (6) 1.323 (5) 62.9 (4) 66.3 (4) 50.7 (3) This work 12 1.271 (3) 1.588 (3) 1.446 (3) 1.344 (3) 59.55 (14) 71.20 (16) 49.26 (12) This work 14 ligand 1 1.294 (8) 1.550 (8) 1.476 (8) 1.326 (8) 61.8 (4) 67.7 (4) 50.5 (4) This work 14 ligand 2 1.250 (8) 1.519 (8) 1.465 (9) 1.332 (8) 63.0 (4) 67.5 (5) 49.5 (4) This work

4. Conclusion

The 3-amino-2H-azirines 10–12 were synthesized with the aim of separating the stereoisomers after their direct crystallization or crystallization of their PdCl₂ com­plexes, as exemplified by com­plex 14, which incorporates com­pound 10 as ligands. Unfortunately, this objective was not achieved, as the crystal structures of 11 and 14 revealed the presence of a diastereoisomeric mixture of the azirines in the crystals, and the crystal structure of 12 was inconclusive as to whether the chosen crystal was enanti­omerically pure or also a racemic mixture that had crystallized as an inversion twin. Nonetheless, the study has added to the small number of recorded crystal structures of amino­azirines with their unusually long formal ring N—C single bonds.