1. Introduction

The tricyclic dibenzo[b,e]azepine system constitutes a class of nitro­gen-containing heterocyclic compounds whose chemistry continues to be of inter­est, because of the action of com­pounds containing this system as analgesics and as anti­cancer, anti­depressive, anti­histaminic, anti­muscarinic and anti­psy­chotic agents (Al-Qawasmeh et al., 2009). Examples of such compounds in current clinical use include mianserin, racemic 2-methyl-1,2,3,4,10,14b-hexa­hydro­dibenzo[c,f]pyra­zino­[1,2-a]azepine, which is a potent anti­depressant (Dinesh et al., 2014), and epinastine, racemic 3-amino-9,13b-di­hydro-1H-dibenz[c,f]imidazo[1,5-a]azepine, which is an anti­histaminic used in the treatment of allergic conjunctivitis (Liu et al., 2004). The biological potential of these compounds has resulted in considerable synthetic efforts to develop efficient methods for the synthesis of new derivatives of this kind (Andrés et al., 2002; Stappers et al., 2002; Wikström et al., 2002).

In this context, and as part of our own inter­est in the identification of other mol­ecular entities with pharmacological potential, we have for several years studied the chemistry of the synthetically available di­hydro­dibenzo[b,e]azepines (Palma et al., 2004) as building blocks for the construction of novel fused tetra­cyclic azepine systems. Accordingly, we have re­ported the synthesis of tetra­hydro­dibenzo[c,f]thia­zolo[3,2-a]azepine derivatives, compounds in which the dibenzo[b,e]aze­pine nucleus is fused to a thia­zolidin-4-one ring (Palma et al., 2010). We are now developing a simple and efficient synthetic methodology for the preparation of derivatives of the type alkyl 4-oxobenzo[5,6]azepino[3,2,1-ij]quinoline-5-carboxyl­ate. This is a new heterocyclic system in which a benzazepine nucleus is fused to a 4-quinolone system, which is also of great inter­est for both the medicinal chemistry and pharmaceutical industries (Mugnaini et al., 2009), mainly because of their anti­bacterial activity, the best studied biological property of the so-called fluoro­quinolone anti­biotics.

We report here the mol­ecular and supra­molecular structures of three compounds containing fused tetra­cyclic azepine systems, namely 9-ethyl-11-methyl-9,13b-di­hydro­dibenzo[c,f]thia­­zolo[3,2-a]azepin-3(2H)-one, (I), 9-ethyl-7,12-dimethyl-9,13b-di­hydro­dibenzo[c,f]thia­zolo[3,2-a]azepin-3(2H)-one, (II), and ethyl 2-chloro-13-ethyl-4-oxo-8,13-di­hydro-4H-benzo[5,6]azepino[3,2,1-ij]quinoline-5-carboxyl­ate, (III) (Figs. 1–3). Compounds (I) and (II) were synthesized from the corresponding di­hydro­dibenzo[b,e]azepines (A) and (B) (see Scheme 1) according to a previously described procedure (Palma et al., 2010), in which the tricyclic precursors (A) and (B) were first subjected to oxidation using pyridinium chloro­chromate, followed by cyclo­condensation with thio­glycolic acid to give (I) and (II). Compound (III) was synthesized from di­hydro­dibenzo[b,e]azepine (C) employing the modified Gould–Jacobs reaction, in which an alk­oxy­methyl­enemalonate derivative, here diethyl 2-(meth­oxy­methyl­ene)malonate, reacts with the amino group of the precursor with displacement of the eth­oxy unit by the N atom giving the inter­mediate (D), followed by benzannulation to give the quinolone derivative (III) (see Scheme 2).

Figure 1 The mol­ecular structures of the two independent mol­ecules of compound (I), showing (a) mol­ecule 1, which has the (9R,15R) configuration, and (b) mol­ecule 2, which has the (9S,15S) configuration. Displacement ellipsoids are drawn at the 30% probability level.

Figure 2 The mol­ecular structure of the (9R,15R) enanti­omer of compound (II). Displacement ellipsoids are drawn at the 30% probability level.

Figure 3 The mol­ecular structures of the disordered components of compound (III), showing (a) the major R enanti­omer, (b) the minor S enanti­omer and (c) the two disorder components together, with the bonds in the major form shown as full lines and those in the minor form shown as broken lines. Displacement ellipsoids are drawn at the 30% probability level and, for the sake of clarity, the majority of the atom labels have been omitted from part (c).

2. Experimental

2.3. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 1. For compounds (I) and (II), all H atoms were located in difference maps and subsequently treated as riding atoms in geometrically idealized positions, with C—H distances of 0.95 (aromatic), 0.98 (meth­yl), 0.99 (methylene) or 1.00 Å (methine) for (I), and 0.93, 0.96, 0.97 or 0.98 Å for the corresponding bond types in (II), and with, in each case, U_iso(H) = kU_eq(C), where k = 1.5 for the methyl groups, which were permitted to rotate but not to tilt, and 1.2 for all other H atoms. The correct absolute configuration for compound (I) was established using both the Flack x parameter (Flack, 1983), x = 0.007 (6), calculated (Parsons et al., 2013) using 4787 quotients of the type [(I⁺) − (I⁻)]/[(I⁺) + (I⁻)], and the Hooft y parameter (Hooft et al., 2010) y = 0.001 (7). It was apparent from an early stage in the refinement of compound (III) that the mol­ecules exhibited configurational disorder, such that the reference site was occupied by partial-occupancy mol­ecules of both R and S configuration having markedly unequal occupancies. For the minor component, having the S configuration, the bonded distances and the 1,3 nonbonded distances were restrained to be the same as the corresponding distances in the major component, having an R configuration, subject to s.u. values of 0.01 and 0.02 Å, respectively; in addition, the anisotropic displacement parameters for pairs of atoms occupying similar regions of physical space were constrained to be identical. The H atoms in the major component were all located in difference maps and then treated as riding atoms in geometrically idealized positions, with C—H = 0.95 (alkenyl and aromatic), 0.98 (meth­yl), 0.99 (methylene) or 1.00 Å (methine), and with U_iso(H) defined as for (I) and (II). In the final analysis of variance for compound (II), there was a negative value, −0.346, of K = mean(F_o²)/mean(F_c²) for the group of 409 very weak reflections having F_c/F_c(max) in the range 0.000 < F_c/F_c(max) < 0.006, and for compound (III) there was a large value, 5.504, of K for the group of 382 very weak reflections having F_c/F_c(max) in the range 0.000 < F_c/F_c(max) < 0.015.

Table 1 Experimental details   (I) (II) (III) Crystal data Chemical formula C19H19NOS C20H21NOS C22H20ClNO3 Mr 309.41 323.44 381.84 Crystal system, space group Monoclinic, P21 Monoclinic, C2/c Triclinic, P Temperature (K) 100 298 120 a, b, c (Å) 11.4261 (5), 8.1847 (3), 16.8243 (6) 18.1021 (12), 12.4436 (8), 14.8429 (9) 6.8533 (16), 10.612 (5), 13.561 (3) α, β, γ (°) 90, 93.067 (2), 90 90, 97.645 (3), 90 72.45 (4), 75.840 (19), 82.46 (2) V (Å3) 1571.14 (11) 3313.7 (4) 910.0 (6) Z 4 8 2 Radiation type Mo Kα Mo Kα Mo Kα μ (mm−1) 0.21 0.20 0.23 Crystal size (mm) 0.40 × 0.35 × 0.22 0.23 × 0.22 × 0.20 0.26 × 0.15 × 0.13   Data collection Diffractometer Bruker Kappa APEXII Bruker Kappa APEXII Nonius KappaCCD Absorption correction Multi-scan (SADABS; Bruker, 2006) Multi-scan (SADABS; Bruker, 2006) Multi-scan (SADABS; Sheldrick, 2003) Tmin, Tmax 0.823, 0.955 0.818, 0.961 0.845, 0.970 No. of measured, independent and observed [I > 2σ(I)] reflections 61785, 11002, 10697 30952, 3402, 2307 20183, 3776, 2195 Rint 0.025 0.048 0.154 (sin θ/λ)max (Å−1) 0.757 0.626 0.629   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.029, 0.079, 1.05 0.060, 0.168, 1.05 0.065, 0.118, 1.06 No. of reflections 11002 3402 3776 No. of parameters 401 211 322 No. of restraints 1 0 74 H-atom treatment H-atom parameters constrained H-atom parameters constrained H-atom parameters constrained Δρmax, Δρmin (e Å−3) 0.37, −0.21 0.57, −0.45 0.29, −0.31 Absolute structure See §2.3 – – Computer programs: APEX2 (Bruker, 2006), COLLECT (Nonius, 1998), SAINT (Bruker, 2006), DIRAX/LSQ (Duisenberg et al., 2000), EVALCCD (Duisenberg et al., 2003), SIR92 (Altomare et al., 1994), SIR2014 (Burla et al., 2015), SHELXL2014 (Sheldrick, 2015) and PLATON (Spek, 2009).

3. Results and discussion

The constitutions of compounds (I) and (II) are rather similar, differing only in the number and location of the methyl substituents, which are at position 11 in (I) and at positions 7 and 12 in (II). Despite this close similarity, compound (I) crystallizes with Z′ = 2 in the Sohncke space group P2₁, while (II) crystallizes in the centrosymmetric space group C2/c. In mol­ecule 1 of compound (I), containing atom S11 (Fig. 1a), there are stereogenic centres at atoms C19 and C115; the reference mol­ecule 1 was selected as one having the R configuration at atom C19 and on this basis the configuration at atom C115 is also R, whereas the configurations at atoms C29 and C215 in mol­ecule 2 (Fig. 1b) are both S. Thus, despite crystallizing in the space group P2₁, compound (I) is a racemic mixture of (9R,15R) and (9S,15S) enanti­omers and it is therefore a kryptoracemate (Morales & Fronczek, 1996; Fábián & Brock, 2010; Bernal & Watkins, 2015); a search for possible additional crystallographic symmetry found none. Compound (III) has a stereogenic centre at position 13 and the reference mol­ecule was selected as one having the R configuration at this site. However, it was apparent that the reference site was in fact occupied by partial-occupancy mol­ecules of both R and S configurations (Figs. 3a and 3b), having occupancies of 0.900 (6) and 0.100 (6), respectively. These two enanti­omeric forms occupy similar but not quite identical locations (Fig. 3c). The centrosymmetric space groups of compounds (II) and (III) confirm that these compounds have both crystallized as racemic mixtures. That compounds (I)–(III) are racemic is expected from the racemic nature of the precursors (A)–(C) (Palma et al., 2010), but it is inter­esting to note that for compounds (I) and (II), the stereochemistry at position 15 appears to be wholly controlled by that at position 9 and no evidence was found for the formation of the diastereoisomeric (9RS,15SR) forms.

In each of the two independent mol­ecules of compound (I), the five-membered ring is slightly puckered out of planarity, and the ring-puckering parameters (Cremer & Pople, 1975) show that in each mol­ecule this ring adopts an envelope (Evans & Boeyens, 1989) conformation (Table 2), with the ring folded across the line Cx2—Cx15, where x = 1 or 2 in mol­ecules 1 and 2, respectively; the difference of ca 180° between the φ₂ values for the two mol­ecules in (I) confirms their enanti­omeric relationship. By contrast with (I), the five-membered ring in compound (II) adopts a half-chair conformation in which the ring is twisted about a line through atom C3 and the approximate mid-point of the S1—C15 bond. For idealized half-chair and envelope conformations, the values of φ₂ are (36k + 18)° and 36k°, respectively, where k represents an integer. Within the major disorder form of compound (III), the six-membered heterocyclic ring is slightly puckered into a twist-boat conformation; for an idealized twist-boat conformation; the ring-puckering angles are θ = 90° and φ = (60k + 30)°, where k represents an integer. For the seven-membered ring in each of (I), (II) and the major form of (III), the ring conformations are dominated by the twist-boat sin form 2 (Evans & Boeyens, 1989). By contrast, the most common conformation of the seven-membered ring in tricyclic di­benz­azepines is one inter­mediate between the boat and twist-boat forms (Sanabría et al., 2014), while the most common form in benzopyrimidoazepines is the boat form (cos form 2) (Acosta et al., 2015; Acosta Qu­intero, Palma et al., 2016).

Table 2 Selected geometric parameters (Å, °)   (I), mol­ecule 1 (I), mol­ecule 2 (II) (III), major (III), minor Ring-puckering parameters           Five-membered ring           Q2 0.4627 (12) 0.3979 (12) 0.300 (3)     φ2 359.12 (17) 178.1 (2) 339.0 (5)                 Six-membered ring           Q       0.107 (8) 0.16 (7) θ       87 (4) 112 (26) φ       39 (4) 2(30)             Seven-membered rings           Q 0.9540 (13) 0.9418 (12) 0.981 (3) 0.843 (6) 0.85 (5) φ2 38.32 (8) 217.47 (8) 40.16 (16) 271.8 (4) 267 (4) φ3 286.0 (3) 107.8 (3) 281.6 (7) 9.6 (10) 17 (7)             Dihedral angles 70.84 (4) 65.44 (4) 76.67 (9) 52.8 (2) 66 (3)             Torsion angles           Cx9A—Cx9—Cx91—Cx92 −169.01 (11) 170.60 (10) −173.0 (2)     Cy2A—Cy13—Cy31—Cy32       −69.4 (5) 42 (5) Notes: (i) x = 1 or 2 for mol­ecules 1 and 2, respectively, in (I) and x = nul for (II); y = 1 or 2 for the major- and minor-disorder forms, respectively, in (III); (ii) the ring-puckering angles are calculated for the following atom sequences: five-membered rings Sx1–Cx2–Cx3–Nx4–Cx1, six-membered rings Ny7–Cy3B–Cy3A–Cy4–Cy5–Cy6, and seven-membered rings Nx4–Cx4A–Cx8A–Cx9–Cx9A–Cx14–Cx15 in (I) and (II), and Ny7–Cy3B–Cy3C–Cy13–Cy2A–Cy8A–Cy8 in (III); (iii) the dihedral angles are those between the mean planes of the two aryl rings in each of (I)–(III).

In each of the five independent mol­ecular entities reported here, the dihedral angle between the two aryl rings falls within a fairly narrow range of less than 25° (Table 2). The specification of the mol­ecular conformations is completed by the orientation of the ethyl substituent relative to the seven-membered ring; the torsion angles defining this orientation are very similar in compounds (I) and (II), except for the difference in sign between the two independent mol­ecules in (I) consistent with their enanti­omeric relationship, whereas in (III) this orientation is entirely different (Table 2 and Figs. 1–3).

Despite the close similarity between the constitutions of compounds (I) and (II), the supra­molecular assembly in these two compounds is entirely different. In compound (I), the mol­ecules are linked into complex sheets by a combination of two C—H⋯O hydrogen bonds and two C—H⋯π(arene) hydrogen bonds (Table 3), but the formation of the sheet structure is readily analysed in terms of simple substructures (Ferguson et al., 1998a,b; Gregson et al., 2000). The mol­ecules of type 1 which are related by the 2₁ screw axis along (0, y, ) are linked by C—H⋯O hydrogen bonds to form a C(5) (Bernstein et al., 1995) chain running parallel to the [010] direction. A similar C(5) chain, anti­parallel to the first chain is built from type 2 mol­ecules which are related by the 2₁ screw axis along (0, y, 0); thus each type of C(5) chain contains only a single enanti­omeric form. Two independent C—H⋯π(arene) hydrogen bonds, in which the donors are two adjacent C—H bonds in a type 1 mol­ecule and the acceptors are the two aryl rings of a type 2 mol­ecule, thus precluding the possibility of any additional crystallographic symmetry, link the type 1 chains along (0, y, n + ) to the type 2 chains along (0, y, n), where n represents an integer in each case, to form a sheet lying parallel to (100) (Fig. 4); however, there are no direction-specific inter­actions between adjacent sheets.

Table 3 Parameters (Å, °) for hydrogen bonds and short inter­molecular contacts Cg1–Cg3 represent the centroids of the C29A/C210–C214, C24A/C25–C28/C28A and C9A/C10–C14 rings, respectively. Compound D—H⋯A   D—H H⋯A D⋯A D—H⋯A (I) C115—H115⋯O13i   1.00 2.47 3.3084 (18) 141   C215—H215⋯O23ii   1.00 2.37 3.1681 (18) 136   C112—H112⋯Cg1iii   0.95 2.81 3.6738 (13) 152   C113—H113⋯Cg2iii   0.95 2.85 3.7676 (14) 163 (II) C2—H2B⋯O3iv   0.97 2.57 3.120 (4) 116   C91—H91A⋯Cg3v   0.97 2.82 3.736 (3) 157 (III) C18—H18B⋯O151vi   0.99 2.54 3.483 (9) 159   C19—H19⋯O151vi   0.95 2.54 3.396 (12) 149   C28—H28B⋯O251vi   0.99 2.10 3.13 (7) 159   C29—H29⋯O251vi   0.95 2.75 3.34 (12) 124 Symmetry codes: (i) −x, y + , −z + 1; (ii) −x, y − , −z; (iii) x, y + 1, z; (iv) −x + , −y + , −z + 1; (v) −x + 1, −y + 1, −z + 1; (vi) −x + 1, −y + 2, −z + 1.

Figure 4 A stereoview of part of the crystal structure of compound (I), showing the formation of a hydrogen-bonded sheet parallel to (100) in which chains built from C—H⋯O hydrogen bonds are linked by C—H⋯π(arene) hydrogen bonds. For the sake of clarity, H atoms which are not involved in the motifs shown have been omitted.

In contrast to the complex supra­molecular assembly in compound (I), that in compound (II) is extremely simple. Inversion-related pairs of mol­ecules are linked by paired C—H⋯π(arene) hydrogen bonds to form centrosymmetric dimers, each containing an enanti­omeric pair (Fig. 5), but there are no direction-specific inter­actions between adjacent dimers, so that the supra­molecular assembly is finite and zero-dimensional.

Figure 5 Part of the crystal structure of compound (II), showing the formation of a centrosymmetric hydrogen-bonded dimer. For the sake of clarity, the unit-cell outline and H atoms bonded to C atoms that are not involved in the motif shown have been omitted. The atom marked with an asterisk (*) is at the symmetry position (−x + 1, −y + 1, −z + 1).

The mol­ecules of compound (III) are linked by C—H⋯O hydrogen bonds to form centrosymmetric dimers (Fig. 6). For the major-disorder form, the hydrogen bonds generate a dimer, centred at ( 1, ), characterized by an outer R₂²(18) ring, which encloses an inner R₂²(14) ring flanked by two inversion-related R₂¹(6) rings; for the minor-disorder component, only the R₂²(14) ring is present as the H29⋯O251ⁱ separation [symmetry code: (i) −x + 1, −y + 2, −z + 1] of 2.75 Å is above the sum of the van der Waals radii (Rowland & Taylor, 1996), so that the corresponding C—H⋯O contact cannot be regarded as a hydrogen bond. Dimers of this type are linked into a chain by a single π–π stacking inter­action. The chlorinated aryl rings of the mol­ecules at (x, y, z) and (−x + 2, −y + 1, −z + 1) are strictly parallel, with an inter­planar spacing of 3.368 (3) Å; the ring-centroid separation is 3.649 (4) Å, corresponding to a ring-centroid offset of 1.404 (4) Å. This inter­action links hydrogen-bonded dimers related by translation into a π-stacked chain running parallel to the [10] direction (Fig. 7).

Figure 6 Part of the crystal structure of compound (III), showing the formation by the major-disorder form of a cyclic centrosymmetric hydrogen-bonded dimer. For the sake of clarity, the unit-cell outline and H atoms bonded to C atoms that are not involved in the motif shown have been omitted. Atoms marked with an asterisk (*) are at the symmetry position (−x + 1, −y + 2, −z + 1).

Figure 7 A stereoview of part of the crystal structure of compound (III), showing the formation of a π-stacked chain of hydrogen-bonded dimers running parallel to the [10] direction. For the sake of clarity, the minor-disorder component and H atoms bonded to C atoms that are not involved in the motif shown have been omitted.

It is inter­esting briefly to compare compounds (I)–(III) reported here with the related tetra­cyclic benzopy­rim­ido­aze­pine derivatives (IV) and (V) (see Scheme 3). Firstly, the syntheses of (IV) and (V) utilized a completely different approach (Acosta Qu­intero et al., 2015; Acosta Qu­intero, Burgos et al., 2016) from that employed for the preparation of (I)–(III); the synthesis of compounds (I)–(III) appended an additional ring to a preformed dibenzazepine skeleton, while those for (IV) and (V) were based on the formation of the azepine ring as the final step using an N-pyrimido­indole precursor for (IV) and an N-pyrimido­quinoline precursor for (V). Secondly, the conformation of the azepine ring in compound (IV) differs from the twist-boat form which predominates in (I)–(III) and (V), as this ring contains a significant contribution from the twist-chair form. As a consequence of this, the C-methyl group occupies a quasi-equatorial position in (V), as expected, but a quasi-axial site in (IV) (Acosta Qu­intero, Palma et al., 2016). Thirdly, the supra­molecular aggregation in the structures of (IV) and (V) differs from that in (I)–(III). The mol­ecules of compound (IV) are linked into C(5) chains by C—H⋯N hydrogen bonds, although inter­actions of this type are wholly absent from the structures of (I)–(III), and inversion-related chains of this type are linked into pairs by a π–π stacking inter­action involving the pyrimidine ring. The mol­ecules of compound (V) are linked by C—H⋯π(pyrimidine) inter­actions into cyclic centrosymmetric dimers, somewhat similar to those in the structure of compound (II).

Finally, we note that although the racemic compound (IV) crystallizes in the Sohncke space group P2₁, it does so as a conglomerate rather than as a a kryptoracemate.