Introduction
Rigid structures are emerging in both materials science and medicinal chemistry [1]. Often referred to as bioisosteres, small strained hydrocarbons are used to replace phenyl [2–4] or alkyne groups [5] in well-known compounds, e.g., imatinib [3] and tazarotene [5]. The increase of the three-dimensionality and the disruption of the π-system can lead to improved properties, e.g., increased water-solubility of drug candidates [2] or the electronical separation of a photoswitch and a chromophore [6]. Often used moieties for these kinds of applications are triptycenes, cubanes, bicyclo[2.2.2]octanes (BCOs) and bicyclo[1.1.1]pentanes (BCPs) [1]. In their pioneering work Stepan et al. replaced a para-substituted fluorophenyl ring in the γ-secretase inhibitor BMS-708,163 with a BCP whereby the oral absorption and in vitro metabolic stability could be significantly increased [2]. BCPs are usually derived from [1.1.1]propellane (1) [7]. However, the available methods to synthesize useful BCP building blocks are quite limited and current research focuses on the development of such methods (Scheme 1).
Scheme 1
Summary of the most recent methods to obtain different BCPs from 1.
After the first synthesis of [1.1.1]propellane (1) by Wiberg and Walker in 1982 [8] and the improved route by Szeimies et al. in 1985 [9] the compound and its reactions were intensely investigated [10]. Michl et al. synthesized terminally functionalized polymers derived from 1, so-called [n]staffanes, and discussed their application as rigid tectones [11–12].
The characteristic reactivity of 1 emerges from the strained central bond, which was opened with free radicals in most cases. The reaction with diacetyl and subsequent oxidation leads to the important intermediate bicyclo[1.1.1]pentane-1,3-dicarboxylic acid which provides access to unsymmetrically substituted BCPs (not shown) [13]. It is assumed that the reaction of 1 with nucleophiles also proceeds through a radical mechanism [14–15]. The reaction with alkyl halides, initially described by Michl et al. [16], has recently been further investigated by Anderson et al. (Scheme 1) [17]. Both groups showed that the BCP halide can be lithiated to further modify the products. The opening of 1 with Grignard reagents enables the synthesis of aryl and some alkyl-substituted BCPs and a subsequent cross-coupling reaction [5,18].
To provide bicyclo[1.1.1]pentylamine as a building block in large-scale syntheses, Bunker et al. developed a synthesis of hydrazine BCP via a manganese-catalyzed reaction, which can easily be converted to the corresponding amine [19]. An alternative approach by Baran et al. installs the BCP late-stage at a secondary aliphatic amine via the corresponding turbo-amide [20–21]. Uchiyama et al. investigated the reaction mechanism of a radical multicomponent carboamination of 1. This reaction provides access to internal BCPs next to amines [22].
The reaction of 1 with thiophenol has been known since 1985 and, given the high yield, used to determine the concentration of propellane solutions [23]. Our group investigated this reaction further and proved the generality of the thiol addition [24].
In analogy to this reaction, the insertion of 1 into disulfide bonds has been discovered early, but only very few examples can be found in the literature [10–11 25–28].
In this work, the insertion of [1.1.1]propellane (1) into disulfide bonds was investigated further to enable the synthesis of novel BCP building blocks. After optimizing the reaction conditions, the scope of the reaction was tested, followed by a proof-of-concept that enables a new route to unsymmetrically substituted BCPs.
Results and Discussion
As a starting point, [1.1.1]propellane (1) has been prepared by a published procedure as a solution in diethyl ether [20], quantified by the reaction with thiophenol [23] and stored at −78 °C. Solutions of 1 were obtained with concentrations between 0.40–0.55 M.
Optimization
As some reactions of disulfides with 1 have been reported under different conditions we decided to compare and tune these conditions. Szeimies et al. used azobisisobutyronitrile (AIBN) as a radical initiator and heated the reaction mixture in a Carius tube to 80 °C [27]. Wiberg et al. initiated the reaction by irradiation with a 60 W light bulb overnight [10]. Michl et al. were the first to use UV irradiation in this reaction, but did not report detailed conditions [28]. They used diacetyldithiol and 1 to obtain bisacetylthio[n]staffanes. To find feasible conditions for the insertion of 1 into disulfide bonds, a screening with irradiations of different wavelengths and other reaction conditions was performed (Scheme 2). The screening reaction was set up with 1.0 equiv of diphenyl disulfide (10a) and 1.0 equiv of 1 in diethyl ether at room temperature and the consumption of the starting material was monitored by GC–MS over a period of 1 h (Fig. 1). In this first screening approach the products were not isolated. The relative conversion was determined by integrating the signals of 10a and the products 6a and 11a. No other signals were detected and the sum of the integrals was defined as 100%. This method cannot be used to determine yields or absolute concentrations as no internal standard was added.
Scheme 2
Screening reaction performed with different types of irradiation (see Fig. 1).
Figure 1
Optimization of the reaction conditions. The relative conversion was determined by GC–MS. The use of a radical initiator (di-tert-butyl peroxide, DTBP) led to increased amounts of insoluble polymer.
In the dark, no conversion could be observed at all. The exposure to daylight led to a conversion of less than 10% after 1 h. With a 500 W halogen lamp, 90% of the starting material was consumed after 1 h. By the addition of di-tert-butyl peroxide (DTBP) as a radical initiator, the conversion could be accelerated in the beginning of the measurement. However, after the work-up of the reaction with radical initiator, an insoluble white solid, presumably longer [n]staffanes, was discovered. When the reaction was performed in a 500 W UV reactor (medium-pressure mercury-vapor lamps, 254 nm) without a radical initiator almost full conversion (≈90%) was observed after 15 min.
The use of UV light at room temperature seemed feasible and the conversion was faster than reported by Wiberg et al. [10]. The absence of a radical initiator is advantageous as the formation of longer [n]staffanes is usually promoted by the initiators. After this initial screening a reaction time of 20 min was chosen.
Scope and limitations
The ratio of the products 6a and 11a could easily be changed by the amount of disulfide used in the reaction. We found that 3.0 equiv of the disulfide led to almost exclusive formation of 6a (Table 1, entry 1). These conditions were applied to different aromatic disulfides and the corresponding products were obtained in fair to quantitative yields. The high yields for the BCPs 6 highlight the advantage of this mild method. Wiberg et al. reported a yield of 45% for 6a [10] and Szeimies et al. obtained 63% of 6a and 27% of 11a [27]. Halogen substitutions were tolerated as well as methyl and methoxy groups. All products of substituted aromatic disulfides are previously unreported.
Table 1
Results of the insertion of 1 into aromatic disulfide bonds. The ratio of 1:10 determines the amount of [2]staffane formed.
|
| |||||
| Entry | Disulfide 10 | R | Ratio of 1:10 | Yield 6 [%] | Yield 11 [%] |
|
| |||||
| 1 | 10a | H | 1:3 | 98a | –b |
| 2 | 10a | H | 1:1 | 51c | 5c |
| 3 | 10a | H | 2:1 | 32c | 10c |
| 4 | 10a | H | 3:1 | 33c | 20c |
| 5 | 10b | 4-Cl | 1:3 | 98a | –b |
| 6 | 10b | 4-Cl | 2:1 | 34c | 15c |
| 7 | 10c | 3,5-Cl2 | 1:3 | 96a | –b |
| 8 | 10c | 3,5-Cl2 | 2:1 | 34c | 8c |
| 9 | 10d | 4-Me | 1:3 | 96a | traces |
| 10 | 10d | 4-Me | 2:1 | 35c | 12c |
| 11 | 10e | 4-OMe | 1:3 | 94a | traces |
| 12 | 10f | 2-Ph | 1:3 | 61a | –b |
aIsolated yield, purified by column chromatography. bNot observed. cIsolated yield, purified by preparative TLC.
The analysis of compound 6a by single-crystal X-ray diffraction [29] revealed a distance of 1.844(3) Å between the bridgehead carbons of the BCP unit (Fig. 2).
Figure 2
Molecular structure of 6a (displacement parameters are drawn at 50% probability level), distance C1–C3 1.844(3) Å.
When 2.0 equiv of 1 and 1.0 equiv of 10a were used, the yield of 6a dropped dramatically and the [2]staffane product 11a was obtained in poor yield (Table 1, entry 3). The separation was possible by preparative TLC. It is assumed that longer staffane chains are formed in this reaction. However, the isolation and characterization of these compounds was not successful. The influence of the ratio of 1:10 on the formation of the [2]staffane was also investigated for some of the substituted disulfides. The overall trend was the same for all reactions with yields of around 35% for 6 and between 8–15% for 11. The yield of 11a could be increased to 20% by using a ratio of 3:1 (Table 1, entry 4).
The radical reaction as proposed in Scheme 3 should lead to higher yields of 11 with an increasing amount of 1. As the kinetically controlled reactions depend on the concentration of the reaction partners, the dimerization becomes less dominant with a low concentration of the BCP radical. The propagation with the disulfide proceeds faster as the disulfide concentration is higher. The formation of staffanes seems to be less favored than the propagation with the disulfide. This observation is in accordance with previous calculations and experimental results [17,22].
Scheme 3
Proposed mechanism of the propellane insertion into disulfide bonds.
Insertion into aliphatic disulfides
To investigate the insertion of 1 into aliphatic disulfides, benzyl disulfide 12 was chosen as a model compound. As the formation of thiyl radicals is critical to the reaction and most aliphatic disulfides do not absorb UV light at the used wavelength, radical initiators should be taken into account for other disulfides. However, for 12 the reaction was successful without radical initiator and the BCP 13 was obtained as the main product (Scheme 4). The purification was possible by HPLC (reversed-phase) and the yield was significantly lower compared to the aromatic disulfides. Szeimies et al. also synthesized alkyl-substituted BCP and staffane sulfides with the previously described method (see optimization) in similar yields [27]. Presumably, there are two factors contributing to the lowered yield. The bond dissociation energy (BDE) of dialkyldisulfides is higher than the BDE of diaryl disulfides [30]. Therefore lower concentrations of thiyl radicals are present to initiate the reaction. The second reason could be the absorption of the UV irradiation. In the benzyl group only the aromatic part can absorb the light and a transfer has to take place to promote the homolytic cleavage of the disulfide.
Scheme 4
The insertion of 1 into dibenzyl disulfide (12) led to the formation of BCP 13 and traces of [2]staffane 14. The structure of 14 could be proven by single-crystal X-ray diffraction (displacement parameters are drawn at 50% probability level).
In first purification attempts [2]staffane 14 could be identified in a mixture with 13 in traces. From the product mixture we could obtain single-crystals of 14 to confirm the structure by X-ray diffraction (Scheme 4) [31]. The rod-like structure of the [2]staffane unit now becomes more tangible. The distance in one BCP unit equals 1.857(3) Å (C1–C5) and the two units are 1.491(4) Å apart from each other (C1–C1’).
Reaction with different mixtures of disulfides
The synthesis of useful unsymmetrically substituted BCPs remains a challenge and only few direct routes from 1 are available (see Introduction). The insertion into disulfides could provide an alternative approach. With the two disulfides 10a and 10d as starting materials a product mixture of 6a, 15 and 6d was obtained (Scheme 5). The yields were determined by NMR spectroscopy as the products could not be separated by column chromatography (Fig. 3). Analytical samples could be obtained by purification of this mixture via HPLC (reversed-phase column). If one assumes equal reaction rates for the propellane insertion, independent from the substitution of the disulfide, a product mixture with the ratio 1:2:1 would be expected. The obtained yields of 18, 45 and 24%, respectively differ slightly from this ratio.
Scheme 5
Reaction of propellane (1) with the two disulfides 10a and 10d. When two different disulfides were used, all three possible products were obtained. The yields were determined by NMR spectroscopy (Fig. 3).
Figure 3
NMR spectra of pure 6a (green) and 6d (red) and the obtained mixture with the new compound 15 (blue).
To facilitate the separation of the products we switched the disulfides used in this reaction to 10a and 10e (Scheme 6). With the bigger difference in polarity of the substituents, the products 6a, 16 and 6e could be separated by column chromatography and preparative TLC. Again, we observed a deviation from the expected product ratio. This leads to the assumption that the 4-methoxybenzenethiyl radical is either formed faster and/or reacts more rapidly with 1 than the corresponding benzenethiyl radical. The calculated BDE (DFT calculation) of 10e is slightly lower with 49.0 kcal/mol compared to 10a with 54.5 kcal/mol [32]. This difference hints towards the faster formation of the 4-methoxybenzenethiyl radical, but the values are in the same region. To ascertain the main factor for this trend further investigations are necessary. We observed the same trend in the thiol addition to 1, when thiophenol and 4-methoxythiophenol were used in a competitive reaction [24].
Scheme 6
The reaction of 1 with the two disulfides 10a and 10e led to the known products 6a, 6e and to the unsymmetrically substituted BCP 16 as the main product. The compounds could be separated by column chromatography and preparative TLC. The structure of 16 could be confirmed by single-crystal X-ray diffraction (displacement parameters are drawn at 50% probability level).
The structure of 16 could be confirmed by single-crystal X-ray diffraction [33]. With 16 as the main product of this reaction, this method provides new access to unsymmetrically substituted BCPs directly from 1 and purely symmetrical starting materials. This finding will be pursued with a selective cleavage or oxidation of one sulfide in further studies.
Conclusion
The reported reaction of [1.1.1]propellane with aromatic and to a certain extend aliphatic disulfides provides access to [2]staffanes and symmetrical and unsymmetrical BCPs. The separation of these compounds is often challenging due to the similar polarity. However, the reaction conditions can be tuned to obtain solely the BCP compound in high yields. By mixing two aromatic disulfides in this reaction three different products can be obtained, with the unsymmetrically substituted compound as the main product. This method will become particularly interesting if the two sulfides of the product can be modified individually. This approach to unsymmetrically substituted BCPs will be further investigated.
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