1. Introduction

The generation of salt forms of an active pharmaceutical ingredient (API) is a well-known process used by the pharmaceutical industry to change important material properties of the API. Idealizing properties such as solubility, stability or hygroscopicity is important to the development of an effective and commercially successful API (Stahl & Wermuth, 2008). It is generally accepted that there are links between the solid-state structure and the material properties of inter­est, and that a greater understanding of such structure-to-property correlations should help to rationalize salt screening and other form-choice processes.

Phenyl­ethyl­amine (PEA) com­pounds (Scheme 1) have long been known to have a large variety of pharmaceutical and bio­logical roles (e.g. Brown et al., 1979; Drew et al., 1978; Broadley, 2010; Dennany et al., 2015). Due to their favourable handling characteristics, several have been used in studies where relatively large numbers of salt forms of a given API have been crystallographically characterized and the structures then used to systematically investigate material properties. The earliest examples of this are the studies by Davey investigating the structures and crystal properties of pseudo­ephedrine salts forms and their relationships to solubility (Black et al., 2007; Collier et al., 2006). A problem with similar studies using large numbers of crystal structures is how to simply com­pare and contrast multiple structures. One solution to this are the packing similarity tools available within Mercury (Taylor & Wood, 2019; Childs et al., 2009; Macrae et al., 2020). In the area of PEA salt forms, these tools have been used to investigate hydrate formation in tyramine salt forms (Briggs et al., 2012), and density and melting point in pairs of enanti­opure and racemic methyl­ephedrine salt forms (Kennedy et al., 2011). An intriguing result using this approach was that groups of methyl­ephedrine salt forms that showed isostructural cation packing also showed tighter correlation between aqueous solubility and melting point than did similar salt forms that were not part of isostructural packing groups (de Moraes et al., 2017).

Dopamine is a biologically significant member of the PEA family and arguably the most well known. In the brain it is a neurotransmitter and it is known to play a role in a wide range of human bodily functions, including motor control, motivation, gastrointestinal tract function and operation of the im­mune system. It is well known that loss of the ability to secrete dopamine leads to Parkinson's disease (e.g. Wenzel et al., 2015; Schultz, 2007). Perhaps less well known is that dopamine in the form of its HCl salt is used as an API, for instance, in the treatment of neonatal shock (Noori et al., 2003). Some crystallographic work has been undertaken on forms of dopamine. Dopamine itself has been shown to exist in the solid as a zwitterionic form, with deprotonation of the OH group meta to the ethyl­amine substituent (Cruickshank et al., 2013). The structures of some simple salt forms of dopamine are also know. These include forms with inorganic anions [the halides DOPAMN01, QQQAEJ02 and ATOLUR04 (Giesecke, 1980; Pike & Dziura, 2013; Ivanova & Spiteller, 2017); the nitrate CIZYAN (Gatfaoui et al., 2014); and the perchlorate OGEGAJ (Boghaei et al., 2008)] and four forms with small to medium sized organic anions (ATOLIF, ATOMAY, RAWDEB and MIYLOV; Ivanova & Spiteller, 2010; Feng et al., 2017; Ohba & Ito, 2002). This gives a total of ten relevant literature structures available from the Cambridge Structural Database (CSD, Version 5.43, update of November 2022, Groom et al., 2016). To this data set we herein add the structures of the benzoate, 4-nitro­benzoate, ethane­disulfonate and 4-hy­droxy­benzene­sulfonate salt forms of dopamine. The new structures are described and a com­parative analysis of the packing of dopamine and its salt forms, and those of the closely related PEA species tyramine is presented.

2. Experimental

2.2. Refinement

The anion of IV was found to be disordered, with the benzene ring rotated by approximately 52° around an axis that runs through atoms S1, C9, C12 and O6. Thus, four aromatic C—H groups were each modelled as split over two sites with occupancies refined to a 50:50 ratio. No further restraints or constraints were required to satisfactorily model these disordered atoms. For I, II and III, all H atoms bonded to O or N atoms were positioned as found by difference synthesis and refined freely and isotropically. For IV, restraints on the O—H bond lengths were required and they were set to 0.88 (1) Å. For I to IV, H atoms bound to C atoms were placed in idealized positions and refined in riding modes. C—H bond lengths of 0.95 and 0.99 Å were used for CH and CH₂ groups, respectively, and U_iso(H) values were set at 1.2U_eq(C) of the parent atom. Further crystallographic details and refinement parameters are given in Table 1.

Table 1 Experimental details For all structures: Z = 4. Experiments were carried out at 123 K. Absorption was corrected for by multi-scan methods (CrysAlis PRO; Rigaku OD, 2019). H atoms were treated by a mixture of independent and constrained refinement.   I II III IV Crystal data Chemical formula C8H12NO2+·C7H5O2− C8H12NO2+·C7H4NO4− 2C8H12NO2+·C2H4O6S22− C8H12NO2+·C6H5O4S−·H2O Mr 275.29 320.30 496.54 345.36 Crystal system, space group Monoclinic, P21/c Monoclinic, P21/n Orthorhombic, Pbca Monoclinic, P21/c a, b, c (Å) 11.7637 (6), 11.7460 (5), 10.3316 (5) 7.4993 (2), 18.5051 (5), 10.7610 (3) 10.6328 (5), 8.5651 (5), 23.8669 (13) 17.4085 (8), 11.9234 (5), 7.6779 (3) α, β, γ (°) 90, 111.384 (6), 90 90, 99.628 (3), 90 90, 90, 90 90, 95.273 (4), 90 V (Å3) 1329.30 (12) 1472.33 (7) 2173.6 (2) 1586.95 (12) Radiation type Cu Kα Mo Kα Cu Kα Cu Kα μ (mm−1) 0.83 0.11 2.75 2.15 Crystal size (mm) 0.35 × 0.10 × 0.02 0.35 × 0.25 × 0.05 0.30 × 0.15 × 0.05 0.5 × 0.15 × 0.07   Data collection Diffractometer Oxford Diffraction Gemini S Oxford Diffraction Xcalibur E Oxford Diffraction Gemini S Oxford Diffraction Gemini S Tmin, Tmax 0.761, 1.000 0.928, 1.000 0.500, 1.000 0.653, 1.000 No. of measured, independent and observed [I > 2σ(I)] reflections 5127, 2614, 2033 7174, 3573, 2620 7583, 2172, 1924 6603, 3113, 2474 Rint 0.026 0.026 0.032 0.040 (sin θ/λ)max (Å−1) 0.619 0.682 0.626 0.621   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.060, 0.171, 1.02 0.048, 0.112, 1.03 0.041, 0.134, 1.14 0.057, 0.169, 1.04 No. of reflections 2614 3573 2172 3113 No. of parameters 201 228 165 277 No. of restraints 0 0 0 5 Δρmax, Δρmin (e Å−3) 0.63, −0.27 0.34, −0.23 0.62, −0.57 0.81, −0.41 Computer programs: CrysAlis PRO (Rigaku OD, 2019), SIR92 (Altomare et al., 1994), SHELXS (Sheldrick, 2015a), SHELXL2018 (Sheldrick, 2015b), Mercury (Macrae et al., 2020) and SHELXL in WinGX (Farrugia, 2012).

3. Results and discussion

The structures of I–IV are shown in Figs. 1–4, with crystallographic parameters detailed in Table 1 and hydrogen-bonding parameters detailed in Tables 2–5. The asymmetric units of both I and II consist of a dopamine cation and a (substituted) benzoate anion. The asymmetric unit of III consists of a dopamine cation and half of an ethane­disulfonate dianion. Here the dianion has a crystallographic centre of symmetry in the middle of its C—C bond. Finally, IV is a monohydrate and so the asymmetric unit consists of a dopamine cation, a disordered hy­droxy­benzene­sulfonate anion and a water mol­ecule. In all four cases, the dopamine moiety has been protonated at the amine group and the H atom of the meta-hy­droxy substituent is orientated towards the O atom of the para-hy­droxy group to form an intra­molecular hydrogen bond. All of the ethyl­ammonium chains adopt extended con­formations, with the N1—C1—C2—C3 torsion angles ranging from −168.89 (14) to 176.39 (16)°. This corresponds to an anti arrangement of the large aromatic and NH₃ substituents on the C1—C2 fragment. The relevant literature salt forms as listed in Table 6 also adopt extended conformations, with the exception of the di­nitro­benzoate salt MIYLOV. This is the only form to have a folded conformation, displaying an N—C—C—C torsion angle of 60.5° (Ohba & Ito, 2002). This distribution of conformations resembles that found for the salt forms of the closely related tyramine cation. Of 42 tyramine salt forms, the majority displayed extended conformations and only four displayed a folded conformation (Briggs et al., 2012).

Table 2 Hydrogen-bond geometry (Å, °) for I D—H⋯A D—H H⋯A D⋯A D—H⋯A O1—H1H⋯O2 0.84 (4) 2.29 (4) 2.736 (3) 113 (3) O1—H1H⋯O3i 0.84 (4) 2.17 (4) 2.872 (3) 141 (3) O2—H2H⋯O4ii 0.85 (4) 1.83 (4) 2.666 (2) 171 (3) N1—H1N⋯O4iii 0.98 (3) 1.87 (4) 2.834 (3) 167 (3) N1—H2N⋯O3 0.95 (3) 1.93 (3) 2.867 (3) 171 (3) N1—H3N⋯O3iv 0.87 (4) 2.04 (4) 2.866 (3) 156 (3) Symmetry codes: (i) x+1, y, z; (ii) ; (iii) ; (iv) .

Table 3 Hydrogen-bond geometry (Å, °) for II D—H⋯A D—H H⋯A D⋯A D—H⋯A O1—H1H⋯O2 0.87 (2) 2.31 (2) 2.7384 (17) 110.4 (19) O1—H1H⋯O4i 0.87 (2) 1.99 (2) 2.8030 (17) 156 (2) O2—H2H⋯O3ii 0.94 (2) 1.64 (2) 2.5780 (16) 178 (2) N1—H1N⋯O4iii 0.97 (2) 1.80 (3) 2.763 (2) 170 (2) N1—H2N⋯O2iv 0.90 (2) 2.44 (2) 2.9890 (18) 119.7 (16) N1—H2N⋯O6iv 0.90 (2) 2.41 (2) 3.095 (2) 133.8 (17) N1—H3N⋯O2v 0.88 (2) 2.50 (2) 2.9956 (19) 116.6 (15) N1—H3N⋯O4vi 0.88 (2) 2.50 (2) 3.1125 (18) 127.5 (16) N1—H3N⋯O5vii 0.88 (2) 2.48 (2) 3.181 (2) 137.3 (16) Symmetry codes: (i) ; (ii) x, y, z+1; (iii) ; (iv) ; (v) ; (vi) ; (vii) .

Table 4 Hydrogen-bond geometry (Å, °) for III D—H⋯A D—H H⋯A D⋯A D—H⋯A O1—H1H⋯O2 0.85 (3) 2.32 (3) 2.746 (2) 112 (2) O1—H1H⋯O3i 0.85 (3) 2.02 (3) 2.807 (2) 154 (3) O2—H2H⋯O4ii 0.89 (3) 1.85 (3) 2.727 (2) 167 (3) N1—H1N⋯O5iii 0.90 (3) 1.89 (3) 2.762 (2) 163 (2) N1—H2N⋯O2iv 0.85 (3) 2.11 (3) 2.890 (2) 152 (2) N1—H2N⋯O3v 0.85 (3) 2.49 (3) 2.974 (2) 117 (2) N1—H3N⋯O4vi 0.89 (3) 2.00 (3) 2.776 (2) 146 (3) N1—H3N⋯O5vii 0.89 (3) 2.61 (3) 3.112 (2) 117 (2) Symmetry codes: (i) ; (ii) ; (iii) ; (iv) ; (v) ; (vi) ; (vii) .

Table 5 Hydrogen-bond geometry (Å, °) for IV D—H⋯A D—H H⋯A D⋯A D—H⋯A O1—H1H⋯O2 0.87 (1) 2.28 (3) 2.749 (3) 114 (3) O1—H1H⋯O3i 0.87 (1) 1.95 (2) 2.754 (3) 152 (3) O2—H2H⋯O1Wii 0.88 (1) 1.84 (2) 2.693 (3) 164 (4) N1—H1N⋯O4iii 0.86 (4) 1.99 (4) 2.850 (3) 178 (4) N1—H2N⋯O5 0.86 (4) 1.91 (4) 2.766 (3) 172 (3) N1—H3N⋯O3iv 0.86 (4) 2.27 (4) 2.927 (3) 133 (3) N1—H3N⋯O6v 0.86 (4) 2.46 (4) 3.005 (3) 122 (3) O6—H3H⋯O1Wv 0.88 (1) 1.83 (2) 2.686 (3) 164 (4) O1W—H1W⋯O2vi 0.88 (1) 1.88 (1) 2.752 (3) 175 (4) O1W—H2W⋯O4 0.88 (1) 1.82 (1) 2.698 (3) 177 (4) Symmetry codes: (i) ; (ii) ; (iii) ; (iv) ; (v) ; (vi) .

Table 6 Available crystal structures of dopamine forms CSD refcode Anion Solvent Comment Reference TIRZAX None – free base structure none Zwitterion Cruickshank et al. (2013) DOPAMN01 Chloride none   Giesecke (1980) QQQAEJ02 Bromide none   Pike & Dziura (2013) ATOLUR04 Iodide none H-atom positions changed Ivanova & Spiteller (2017) CIZYAN Nitrate none Z′ = 2 Gatfaoui et al. (2014) OGEGAJ Perchlorate none   Boghaei et al. (2008) ATOLIF 3-Carb­oxy-4-hy­droxy­benzene­sulfonate 1.5 H2O H-atom positions changed Ivanova & Spiteller (2010) ATOMAY Hydrogen squarate none H-atom positions changed Ivanova & Spiteller (2010) RAWDEB Pyrene­tetra­sulfonate 5 H2O Contains 1 dopamine and 3 guanidinium cations Feng et al. (2017) MIYLOV 3,5-Di­nitro­benzoate none   Ohba & Ito (2002) I Benzoate none   This work II 4-Nitro­benzoate none   This work III Ethane­disulfonate none   This work IV 4-Hy­droxy­benzene­sulfonate 1 H2O Disordered anion This work

Figure 1 View of the asymmetric unit contents of I, with non-H atoms shown as 50% probability displacement ellipsoids. Here and in Figs. 2–4, H atoms are drawn as spheres of arbitrary size.

Figure 2 View of the asymmetric unit contents of II, with non-H atoms shown as 50% probability displacement ellipsoids.

Figure 3 View of the asymmetric unit contents of III, extended to show the com­plete dianion generated by the inversion centre in the C—C bond. Non-H atoms are shown as 50% probability displacement ellipsoids.

Figure 4 View of the asymmetric unit contents of IV, with disorder of atoms C10, C11, C13 and C14 hidden for clarity. Non-H atoms are shown as 50% probability displacement ellipsoids.

The dopamine cations of I–IV utilize all three NH groups and both OH groups as hydrogen-bond donors, but apart from that, there is little similarity between them and in detail each acts in a different manner. As shown in Table 7, in benzoate I all potential donors make a single hydrogen bond to an O atom of a benzoate COO group. Here, none of the atoms of the cation acts as an acceptor and hydrogen bonds exist only between cations and anions. In II, the number of potential hydrogen-bond acceptors is increased by the inclusion of an NO₂ group on the anion. This leads to the cation making extra donor inter­actions, with one NH group and the para-OH group both acting as bifurcated donors to two hydro­gen bonds. Again, no atom of the cation acts as an acceptor and all hydrogen bonds are formed between cations and anions. In III, all five cation donor groups make single hydrogen bonds, but in contrast to I and II, the para-OH group also acts as an acceptor, accepting a hydrogen-bond contact from a neighbouring RNH₃ group. Thus, in III, there are hydrogen bonds both between cations and anions, and between pairs of cations. In the hydrate IV, one of the NH groups makes a bifurcated donor inter­action with two neighbouring SO₃ groups and all other cation donor atoms make single hydrogen bonds. That from the para-OH group donates to a water mol­ecule, but all others are to anions. The para-OH group also accepts a hydrogen bond from a water mol­ecule. In IV, hydrogen bonds link cations to anions, and both cations and anions to water. However, unlike III, there are no cation-to-cation hydrogen-bond contacts.

A large-scale structural study on tyramine salt forms identified two common hydrogen-bonding motifs that co-existed in 19 of 24 benzoate and sulfonate salts of that com­pound (Briggs et al., 2012). These motifs were both one-dimensional (1D) chain structures, one of graph set C₂²(6) corresponding to an (⋯OXO⋯HNH⋯)_n (X = C or S) linkage and one of graph set C₂²(13) corresponding to COO or SO₃ groups bonding to both the NH₃ head and the para-OH tail of the cation. Here only structures I and III show both motifs. They also have an additional C₂²(12) motif. This latter is equivalent to the C₂²(13) motif, but utilizes the extra meta-OH group of dopamine rather than the para-OH group which is common to both dopamine and tyramine. Figs. 5 and 6 illustrate these hydro­gen-bonded-chain features. Structure IV contains both the C₂²(6) and the C₂²(12) motifs, but the para-OH group of this hydrate only hydrogen bonds to water mol­ecules and thus the C₂²(13) motif does not occur here. In contrast, of the three motifs described above, the nitro­benzoate salt II only displays the C₂²(13) chain. In the hydrogen bonding of structure II, ring motifs become prevalent, including that formed by a tetra­mer consisting of two cations and two anions. These are linked by hydrogen bonding between the catechol moieties and the carboxyl­ate groups in an R₄⁴(18) motif. This coplanar tetra­mer is then capped on each side of the plane through hydrogen bonds to the RNH₃ groups of two further cations, as shown in Fig. 7.

Figure 5 Part of the 1D C22(6) motif found in III. The hydrogen-bonded chain propagates parallel to the a direction.

Figure 6 An illustration showing the repeating core of the C22(13) motif, utilizing the para-OH group, of structure I. A similar C22(12) motif, using the same functional groups but utilizing the meta-OH group rather than the para-OH group, also exists here.

Figure 7 A central hydrogen-bonding motif in II consisting of four coplanar groups linked via the catechol and carboxyl­ate groups. This unit is capped top and bottom by hydrogen bonds to the RNH3 group of the cation.

On attempting to com­pare the hydrogen-bonding behaviour of dopamine cations in structures I–IV with that in the literature salt forms, a problem was observed. The H-atom positions recovered for the structures of ATOLIF, ATOMAY and, to a certain extent, ATOLUR04 appeared unusual (Fig. 8) (Ivanova & Spiteller, 2010, 2017). As well as unusual out-of-plane conformations, those groups which would be expected to be strong hydrogen-bond donors did not connect with geometrically reasonable acceptor atoms, in contradiction to Etter's rules (Etter, 1990). In all three cases, alternative H-atom positions that did give typical hydrogen-bond inter­actions were available. Thus, for these structures, before hydrogen-bonding motifs were analysed, the H atoms were removed and manually replaced with the H atoms situated so as to give typical hydrogen-bonding geometries. For the hydrate ATOLUR04, H atoms were missing from the water mol­ecule sites. Thus, before analysis, these H atoms were also added in geometrically reasonable expected positions. All further discussion of the hydrogen bonding of these three com­­pounds thus refers to the edited structures. Atomic structures for these edited structures are given in CIF format in the supporting information.

Figure 8 (a) The structure of ATOMAY as recovered from the CSD. Note the unusual out-of-plane geometry of the H atoms of the OH substituents. These out-of-plane H atoms do not form hydrogen bonds with neighbouring ions. (b) The structure of ATOMAY edited so as to place H atoms in-plane and in geometries that maximize hydrogen bonding.

When examining all 13 available salt forms of dopamine in Table 7, it becomes apparent that the hydrogen-bonding be­haviour of the cation is very variable. Of 14 crystallo­graphically independent dopamine fragments, only two, those of the chloride DOPAMN01 and the bromide QQQEAJ01, have the same set of inter­actions originating from the dopamine cation. Furthermore, none of the literature carboxyl­ate or sulfonate structures feature the combination of C₂²(6) and C₂²(13) chains that is found to be prevalent in tyramine salt forms (Briggs et al., 2012). The halide salt forms of dopamine (Cl, Br and I) do though present the C₂¹(4), C₂¹(11) and C₂¹(10) chains that are the monoatomic ion equivalent of the three motifs discussed above for COO- and SO₃-based ions. Finally, it is noted that the ladder-like structures commonly seen for other carboxyl­ate salt forms of RNH₃⁺ species (Kinbara et al., 1996) are found for neither dopamine salt forms nor for tyramine salt forms.

In an attempt to find further com­parable features across the structural group, use was made of the `crystal packing similarity' module within Mercury (Macrae et al., 2020; Childs et al., 2009). This was used to investigate similarity in the cation packing across the available dopamine forms by investigating geometrical similarity between small clusters of dopamine cations. In doing so other species present, such as anions and solvent mol­ecules, were ignored. An initial calculation using only the dopamine structures identified that the chloride and bromide salts of dopamine were isostructural at a cluster size of 15 cations, and that the iodide and perchlorate salt forms were similarly isostructural (Figs. 9 and 10). For the Cl/Br pair, the reported unit cells and space groups clearly indicate that the com­plete structures are both isostructural and isomorphous (Giesecke, 1980; Pike & Dziura, 2013). However, there is no such similarity in the unit cells of the I/ClO₄ pair (Ivanova & Spiteller, 2017; Boghaei et al., 2008).

Figure 9 Overlay diagram showing the packing of 15 dopamine cations of the chloride structure (multicoloured) and 15 dopamine cations of the bromide structure (green). The r.m.s. value is 0.210 Å. Anions have been omitted for clarity.

Figure 10 Overlay diagram showing the packing of 15 dopamine cations of the perchlorate structure (multicoloured) and 15 dopamine cations of the iodide structure (green). The r.m.s. value is 0.451 Å. Anions have been omitted for clarity.

More inter­esting results were obtained when the packing similarity module was applied to a data set that included both the available dopamine forms and those of tyramine. This time six groups of structures with similar cation packing arrays at the level of a 15 from 15 match were identified (Table 8). Group 1 contains only the dopamine I/ClO₄ pair as already seen, and groups 4, 5 and 6 contain only tyramine structures. However, groups 2 and 3 are inter­esting as they contain both dopamine and tyramine structures. Group 2 contains I, the benzoate salt of dopamine, and both the 4-amino- and 4-methyl­benzoate salt forms of tyramine. Group 3 is an expanded version of the dopamine Cl/Br grouping that now also contains III, the ethane­disulfonate salt of dopamine, and six forms of tyramine. These are the chloride, bromide, perchlorate, BF₄ and di­hydrogen phosphate salts of tyramine, and also the neutral hemihydrate of tyramine. (Note: when assessing dopamine structures alone, the ethane­disulfonate structure III was found to be related to the Cl/Br group, but only at a level with 7 from 15 matches. However, the larger and more varied dopamine/tyramine group appears to allow a fuller match.) Each group of Table 8 is com­posed of structures with broadly similar anion types. Thus, for example, group 2 contains only structures with benzoate or para-benzoate anions, and group 3 is com­posed of species with simple inorganic anions or coformers. Beyond this basic similarity though lies a great deal of variation. For example, group 3 encom­passes structures with different cations, with different anions, with and without solvent present, and with neutral PEA species rather than charged ones, see Fig. 11 as an example.

Figure 11 Overlay diagram showing the packing of 15 dopamine cations of the chloride structure (green) and 15 tyramine units of the hemihydrate structure. The r.m.s. value is 0.566 Å. Anions and water mol­ecules have been omitted for clarity.

This, of course, leads to very different hydrogen bonding throughout the structures of these com­pounds. From a chemical identity point of view, the two most different structures of group 3 are the ethane­disulfonate salt of dopamine, III, and the hemihydrate of tyramine, TIRZEB (Cruickshank et al., 2013). The ethane­disulfonate dianion does not fit well with the descriptor used above of a `simple inorganic anion' being as it is both larger than the other anions in this group and doubly charged. This is reconciled simply. The ethane­disulfonate ion lies upon a crystallographic centre of sym­metry, thus making the unique repeating structural part the much smaller `O₃SCH₂' fragment which is a reasonable match to a `simple inorganic anion'. The ethane­disulfonate anion takes the structural place of two anions in other group member structures, such as that of dopamine chloride, DOPAMN01. The intra­molecular S⋯S separation of 4.338 Å in III com­pares well with the inter­molecular Cl⋯Cl distance of 4.303 Å in the chloride. Tyramine hemihydrate, TIRZEB, is an inter­esting structure. Disorder of the phenol H-atom positions in this structure means that the tyramine fragments present are best thought of as a mix of neutral, cationic and zwitterionic forms of tyramine (Cruickshank et al., 2013). This presents some difference to the cationic PEA forms that make up the rest of group 3. Water is obviously a neutral coformer rather than the small anions found in the rest of group 3, but a further difference is stoichiometry. There is only one water mol­ecule per two tyramine fragments in TIRZEB, as opposed to one monoanionic fragment per organic cation in all the other structures of group 3. Despite all this variation in chemical identity and in the type and number of the strong hydrogen-bonding inter­molecular inter­actions, the cations of these groups still adopt similar packing arrangements. Con­versely, similarities in hydrogen bonding do not necessarily seem to lead to similarity in cation packing. One of the few patterns in the hydrogen-bonding behaviour of the dopamine salts is that all three halides have structures based around the same chain-type inter­actions (see above). Despite this hydro­gen-bonding similarity, only the Cl and Br salt forms are found in group 3, with the iodide salt grouping with the perchlorate in group 1. A similar observation that PEA cation packing was not governed by hydrogen-bond formation, though one from a data set that did not feature different cations, was made in a study on methyl­ephedrine salt forms (Kennedy et al., 2011). In a related point, Collier et al. (2006) noted that it was simply the gross amphiphilic nature of the ephedrine cation that dominated packing in structures of its salt forms, rather than the detail of the functional groups or individual inter­action types.