Formation of lithium, sodium and potassium complexes with 1,3,5-tri­amino-1,3,5-tri­deoxy-cis-inositol (taci)

Metal binding of 1,3,5-tri­amino-1,3,5-tri­deoxy-cis-inositol (taci) has been investigated extensively (Hegetschweiler, 1999). As a chelating agent, taci fascinates by its exceptional versatility. This versatility is based on two distinct chair conformations, providing (i) N,N,N-, (ii) N,N,O-, (iii) O,O,N- or (iv) O,O,O-binding. These four binding modes, (i)–(iv), are all restricted to facial coordination. Metal binding to three axial donor groups, as observed in modes (i) or (iv), results in an adamantane-type geometry with low strain for small metal cations (Hancock & Hegetschweiler, 1993; Hegetschweiler et al., 1996). Large metal cations preferentially undergo a `side-on' coordination to the axial–equatorial–axial site of mode (ii) or mode (iii). In continuation of this work, we present here the crystal structures of three complexes with taci, (I) (with Li⁺), (II) (with Na⁺) and (III) (with K⁺).

1,3,5-Tri­amino-1,3,5-tri­deoxy-cis-inositol (taci) was prepared as described by Hegetschweiler et al. (1990), and the metal complexes were obtained following a protocol given by Kradolfer (1995). Colourless single crystals of (I)–(III) suitable for X-ray analysis were grown by slow diffusion of MeOH into the aqueous complex solutions. Elemental analysis, calculated for C₁₂H₃₅I₂LiN₆O₈ (%): C 22.10, H 5.41, N 12.89, I 38.92; found (%): C 22.58, H 5.36, N 12.87, I 39.00; calculated for C₁₂H₃₀IN₆NaO₆ (%): C 28.58, H 6.00, N 16.66, I 25.16; found (%): C 28.81, H 5.91, N 16.40, I 25.00; calculated for C₁₂H₃₀IKN₆O₆ (%): C 27.70, H 5.81, N 16.15, I 24.39; found (%): C 27.79, H 5.70, N 15.85, I 24.50.

Crystal data, data collection and structure refinement details are summarized in Table 1. A preliminary X-ray diffraction study of the Li and Na complexes was reported by Kradolfer (1995). It was realised that the Na complex crystallizes in a trigonal lattice, and in the 1995 study the structure was solved and refined in the space group R3. However, inspection of our data revealed the presence of a centre of inversion and we therefore refined the structure in the space group R3. All H atoms could be located in a difference Fourier map. They were treated as recommended by Müller et al. (2006). A riding model was used for the C-bound H atoms. The positional parameters of the O- and N-bound H atoms were refined with restraints of O—H = 0.84 (s.u.?) Å and 0.88 (s.u.?) Å, and with U_iso(H) = 1.5U_eq(parent). The H4B position of the Li complex was refined with an occupancy of 0.50 (see Discussion).

Li⁺, Na⁺ and K⁺ are all considered as very hard cations and highly oxophilic Lewis acids, and it is not surprising that, in complex with taci, the small Li⁺ cation does indeed undergo a type (iv) coordination [(I)]. For Na⁺ [(II)] and K⁺ [(II)], their low affinity for N-donors conflicts with the more favourable steric prerequisites of a type (iii) binding. However, the high oxophilicity of these cations obviously overrides these steric demands, and in fact all three cations form bis-complexes with a type (iv) structure (Fig. 1).

Similarly, a type (iv) coordination has been observed for the alkaline earth metal cations Mg²⁺, Ca²⁺ and Ba²⁺ (Hegetschweiler et al., 1993). The structure of these alkaline earth metal complexes differs though, as additional water molecules are bonded to the heavier congeners, forming [Ca(taci)₂(H₂O)₂]²⁺, [Sr(taci)₂(H₂O)₃]²⁺ and [Ba(taci)₂(H₂O)₃]²⁺. Such an extension of the coordination sphere was not observed for Na⁺ and K⁺, although the Na and Ca complexes, and the K and Sr complexes, exhibit similar M—O bond lengths. As a consequence, all three alkali metal cations have a coordination number of 6, with a trigonal anti­prismatic geometry. The Na and the K complexes are isotypic. Crystal structure reports of a mononuclear alkali metal cation which is exclusively coordinated to six aliphatic hy­droxy groups are still scarce (Cotton et al., 1988). The crystal structure of an Na–taci 1:1 complex has recently been described (Reiss & Hegetschweiler, 2013). Its structure exhibited a three-dimensional coordination polymer, with the Na⁺ cation again bonded to the three axial O-donors of a taci ligand and, additionally, to an equatorial N-donor of three further taci molecules. The Na centre thus has a mixed NaO₃N₃ coordination and the coordination number is also 6.

The increasing ionic radius in the order Li⁺ < Na⁺ < K⁺ is well reflected in the structures of the three title compounds (Tables 2, 4 and 6). Besides the expected increase in the M—O bond lengths, a slight increase in intra­ligand O···O distances (Li 2.791–2.803 Å; Na 2.993 Å; K 3.026 Å) and a much more pronounced increase in the inter­ligand O···O distances (Li 2.987–3.009 Å; Na 3.704 Å; K 4.345 Å) are observed. Along with these trends, a slight flattening of the cyclo­hexane chair is noted. Puckering parameters (Cremer & Pople, 1975) for the cyclo­hexane chair of (I) are Q = 0.562 (2) Å, θ = 0.0 (2)° and ϕ = 300 (13)°; for (II), Q = 0.534 (2) Å, θ = 0.75 (1)° and ϕ = 0.00°; and for (III), Q = 0.520 (2) Å, θ = 0.00 (1)° and ϕ = 0.00°. Similarly, the increasing ionic radius results in a widening of the C—O—M and inter­ligand O—M—O angles. The intra­ligand O—M—O angles, on the other hand, decrease significantly with increasing ionic radius (Tables 2, 4 and 6). These changes are well in line with the proposed increase in steric strain with increasing ionic size.

All three metal cations are located on a centre of inversion. In addition, the Na⁺ and K⁺ cations lie on a threefold rotation axis. The crystallographically imposed molecular symmetry of the entire [Na(taci)₂]⁺ and [K(taci)₂]⁺ complexes is S₆, although their MO₆ polyhedra adopt D_3d symmetry. Over the entire molecular structures of (II) and (III), the local dihedral mirror planes of the coordination polyhedra are destroyed by a characteristic alignment of the equatorial N—H bond (the axial N—H bond is oriented approximately parallel to the threefold molecular axis). As a consequence, each single taci unit is chiral (C₃ symmetry) and the metal centre (Na, K) is coordinated to an image and mirror image of this particular conformation.

Each taci unit of (II) and (III) is hydrogen-bonded to three neighbouring mirror images by pairwise O—H···N inter­actions of vicinal O—CH₂—CH₂—NH₃ groupings via a centre of inversion (Tables 5 and 7). In terms of graph-set analysis (Bernstein et al., 1995), the resulting ten-membered ring-pattern is represented by R²₂(10). It has recently been shown that the cyclic R²₂(10) motif is a predominant inter­action type for taci molecules in solid-state structures (Neis & Hegetschweiler, 2014). However, in the previous investigations, the taci molecules or Htaci⁺ cations were arranged in indefinite C²₂(12) chains, whereas in the Na and K complexes reported here, the basic R²₂(10) pattern is aligned as complex R⁶₆(30) and R⁶₆(42) rings (Fig. 2a). The honeycomb-type linking generates layers parallel to the ab plane containing large voids, which are occupied by the I^- counterions. The layers are stacked along c in a staggered arrangement, with the centre of the cavity being placed above a metal centre of a neighbouring layer, and consequently the I^- anion exhibits six contacts to the N-bound H atoms of the R⁶₆(30) ring within the same layer and to the axial H atoms of two complex molecules in neighbouring layers. Altogether, the I^- anion is surrounded by six N-bound and six C-bound H atoms, which define a distorted D_3d symmetric icosahedron (Fig. 2b). It is noteworthy that, in the K complex, (III), the N—H···I and C—H···I distances of 3.253 and 3.268 Å, respectively, are of similar size, whereas in the Na complex, (II), with corresponding values of 3.212 and 3.074 Å, the C—H···I distances are significantly shorter.

In contrast with the Na and K complexes, the Li complex, (I), crystallizes as a protonated dication, [Li(taci)(Htaci)]²⁺. Coordination of an alkali metal cation to a protonated taci frame has been observed previously by Bartholomä et al. (2010). Along all three directions (i.e. along the crystallographic a, b and c axes), the dications are arranged in chains by hydrogen bonding, and these are related via a centre of inversion (Table 3). Along [001], the dications form R—NH₂—H···NH₂—R inter­actions (Fig. 3a). This motif is represented by the basic graph set C(10). Analysis of the electron density indicates formation of an asymmetric (N—H···N) hydrogen bond, but it is clear that, in the presence of an I^- counterion, discussion of an H-atom position may be questionable. However, the presence of an asymmetric hydrogen bond is supported by the N···N separation of 2.719 (3) Å. For a symmetric N—H—N bond, with atom H4B located directly on the centre of inversion, a significantly shorter N···N distance would have been expected (Bock et al., 1997; Steiner, 1995; Knop et al., 2001; Majerz & Olovsson, 2010). We therefore inter­preted the structure in terms of a disorder based on a double minimum potential, and the H4B position was refined with an occupancy of 0.50. Based on the C_i symmetry of the complex cation of (I), both ligand entities are half protonated and the complex may be formulated as [Li(H_0.5taci)₂]²⁺.

Along [100] (Fig. 3b), the dications of (I) are connected by R—O—H···NH₂—R hydrogen bonds. Two symmetry-related bonds are formed between two neighbouring cations and the resulting pattern corresponds to a R²₂(14) motif. A similar situation is observed along [010], but an additional water molecule is inserted in the hydrogen bond to form an R—O—H···O(H)—H···NH₂—R structure (Fig. 3c), and the corresponding graph set is R⁴₄(18). The combination of such chain motifs generates a series of large `super-rings'. As an example, the R⁴₄(22) ring shown in Fig. 3(d) follows from a combination of the chain patterns along [001] and [100]. The corresponding voids accommodate the I^- counterions. These I^- anions, which are placed on general positions, form two relatively short contacts to a water molecule and an alcohol OH group, with I···H—O separations of 2.647 and 2.705 Å, respectively. Additional contacts to three amino groups, with I···H separations in the range 2.949–3.119 Å, and to four H—C groups, with I···H separations in the range 3.156–3.313 Å, sum up to a coordination number of 9, with an irregular geometry of the corresponding polyhedron.

It is noteworthy that the calculated densities of the three compounds reported here [(I) 1.943 Mg m^-1, (II) 1.680 Mg m^-1 and (III) 1.629 Mg m^-1) do not coincide with the atomic masses of the corresponding metal centres. The rather high density of the Li complex, (I), is remarkable. A search of the Cambridge Structural Database (CSD, Version?; Allen, 2002) revealed a total of 21 structures containing the elements C, H, N, O, Li and I, with densities ranging from 1.12 to 2.01 Mg m^-1 (average 1.50 Mg m^-1). The high density of our Li complex, (I), is clearly due to the presence of the two I^- counterions per Li⁺ cation, which are required to balance the additional positive charge of the protonated ligand entity. The slightly higher density of the Na complex, (II), compared with the K complex, (III), is less obvious. However, inspection of the unit-cell dimensions for these two isotypic compounds indicates that the larger volume for the K complex is based solely on a lengthening of the unit cell along c. As explained above, this lengthening is a consequence of the larger ionic radius of K⁺, which causes a significant stretching of the trigonal anti­prismatic KO₆ polyhedron along the threefold rotation axis.

In conclusion, the present investigation demonstrates again the high diversity of possible hydrogen-bonding inter­actions for polyamino-polyalcohols (PAPAs). Similar to our previous investigations into hydrogen bonding in the solid-state structures of free taci, taci.HI and a co-crystal of these two components (Hegetschweiler et al., 1993; Reiss et al., 1999; Neis & Hegetschweiler, 2014), amine–alcohol inter­actions of the type R—O—H···N(H₂)—R constitute a predominant structural motif. The pairing mechanism of the vicinal amino­ethanol substructure may result in R²₂(10) ring formation, not only for the free ligand or its protonation products but also in the corresponding metal complexes.