Source: https://pubs.rsc.org/en/content/articlehtml/2019/sc/c8sc05237a
Timestamp: 2019-04-22 11:11:45+00:00

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Difunctionalization of C C bonds is a powerful strategy for the construction of complex compounds with various functional groups.1 In particular, building two C–C bonds tandemly in a single step is highly deserved in terms of structure diversity, step and atom economy. Incoporation of a perfluoroalkyl group in this tandem reaction would be attractive with potential applications in medicinal chemistry, agrochemistry, materials science.2 Along this line, radical-mediated perfluoroalkylative difunctionalization of alkenes, through transition-metal catalysis,3 photoredox catalysis,4 or visible-light activation of electron donor–acceptor (EDA) complexes,5 has played privileged roles in these transformations (Scheme 1, up). Developing a metal- and photo-free method for difunctionalization of alkenes remains an important synthetic goal.
Pyridine skeletons are often served as “privileged” scaffolds in drug design and discovery.6 Radical pyridylation is a useful synthetic methodology for the synthesis of value-added pyridine derivatives, due to the good functional group tolerance and broad substrate scope of these methods.7 The challenge is how to tune the reactivity and selectivity of various radicals in a system. The direct hydroarylation of alkenes with pyridines has also been investigated by transition-metal catalysts.8 However, the simultaneous introduction of the pyridine moiety and other functional groups to alkenes has been rarely reported, which might be attributed to the low reactivity and site-selectivity of the pyridine group.9 Herein, we describe a metal- and photo-free protocol for perfluoroalkylative pyridylation of alkenes, which is mediated by in situ 4-cyanopyridine-boryl radicals (Scheme 1, down).
Scheme 2 (a) 4-cyanopyridine boryl radicals-mediated C–I bond homolysis of perfluorooctyl iodide 1a monitored by 19F NMR; (b) radical trapping experiment.
The proposed reaction mechanism of the alkene perfluoroalkylative pyridylation was postulated in Scheme 3. The following steps may be involved: (1) 4-cyanopyridine-boryl radicals (Int1) are generated from the homolytic cleavage of the B–B bond of B2pin2 by 4-cyanopyridine; (2) Int1 activates the C–I bond of CF3I (1b) to produce the CF3 radical and Int3a, and regenerate 4-cyanopyridine; (3) CF3 radical adds to 4-methylisopropenylbenzene (3a), forming a new alkyl radical (Int4); (4) the selective cross-coupling of Int1 and Int4 by persistent radical effect,14 yields the intermediate Int5, which is hydrolysed to give the alkene perfluoroalkylation product 4b. Notably, Int1 not only catalyze the C–I bond homolysis of perfluoroalkyl halides Rf–X (X = I, Br), but also serves as the pyridine precursor.
Scheme 3 Proposed 4-cyanopyridine-boryl radicals-mediated alkene difunctionalization.
To verify whether the proposed mechanism is thermodynamically or kinetically feasible, we performed DFT calculations with the M06-2X15 functional to explore the free energy profile of the proposed mechanism for the model reaction of 1b and 3a in the presence of Int1 as a reactive intermediate. The reaction mechanism of generating Int1 was reported in our previous works.10c,d,j,k The calculated free energy profile and transition state structures are listed in Fig. 1 (the optimized structures of all minimum species are shown in Fig. S1†). First, the association between the iodine atom of 1b and the carbon atom at the C2 position of the radical Int1 forms an encounter complex (Int2a), which is endergonic by 7.2 kcal mol−1. Then, the transfer of the iodine atom from 1b to Int1 to give the CF3 radical and Int3a involves a barrier of 32.6 kcal mol−1 (viaTS1) and is endergonic by 20.2 kcal mol−1 (relative to the isolated reactants Int1 and 1b). It should be mentioned that the homolytic dissociation energy of C–I bond in CF3I is 49.1 kcal mol−1. There results indicate that the homolysis of C–I bond in CF3I is indeed assisted by Int1. Subsequently, CF3 radical adds to the alkene 3a to generate a new alkyl radical Int4viaTS2, being exothermic by 11.3 kcal mol−1 with a barrier of 29.2 kcal mol−1 (with respect to the separated reactants Int1, 3a and 1b). Finally, the C–C coupling between Int1 and Int4 produces an intermediate Int5 through TS3 with a barrier of 6.8 kcal mol−1 (relative to Int4 and Int1), and the whole process is exothermic by 30.1 kcal mol−1 (with respect to the reactants Int1, 1b and 3a). In addition, the hydrolysis of the intermediate Int5 will produce the final product 4b. The results indicate that the proposed alkene perfluoroalkylation is thermodynamically favorable. Alternatively, the C–I bond homolysis by the 4-cyanopyridine-boryl radicals at the C4 position is also investigated (shown in Fig. S2†). This process is endergonic by 31.0 kcal mol−1, with a barrier of 37.7 kcal mol−1 (relative to Int1 and 1b), suggesting that the pathway is less favorable. Furthermore, we also calculate the isomerization reaction of Int3a (see Fig. S3†). Starting from Int3a, the intramolecular migration of the iodine atom from C2 atom to B atom viaTS4, could yield another isomer Int3b, which further proceeds through the breaking of the B–N bond (viaTS5) to regenerate 4-cyanopyridine. Overall, the rate-determining barrier height of this process is 10.1 kcal mol−1 and endergonic by 2.9 kcal mol−1 (relative to Int3a), indicating that the C–I bond homolysis is a catalytic process by 4-cyanopyridine. Moreover, our calculations suggest that the direct single electron transfer (SET) process between 4-cyanopyridine-boryl radicals and CF3I is highly endergonic by 60.0 kcal mol−1 (see Fig. S4†). Thus, the SET mechanism is unlikely responsible for the generation of the perfluoroalkyl radicals in the reaction.
Fig. 1 Computed Gibbs free energy profile of the alkene carbopyridylation via 4-cyanopyrodine boryl radicals. The optimized structures of transition states are also displayed. Interatomic distances are in Å.
Based on the predicted reactivity, we first examined the proposed alkene difunctionalization using 4-cyanopyridine, perfluorobutyl iodide 1a, 4-methylisopropenylbenzene 3a as model substrates. The optimization details are given in ESI.† We found that the desired product could be obtained in 74% yield at 80 °C in the presence of B2pin2 with N,N-diisopropylethylamine (DIPEA) as additives (Scheme 4a). Control experiments suggest that this transformation occurs via a thermally induced process, as decreased yield was observed at lower temperatures. The requirement of a relatively high temperature (80 °C) are in qualitative accord with the DFT results discussed above. Moreover, the generation of intermediates Int3a (or its isomer Int3b), and the compound 7-like (from the addition of Int1 and the perfluorobutyl radical) in the presence of 1a, 4-cyanopyridine and B2pin2 under the standard conditions were confirmed by high resolution mass spectroscopy (HRMS) experiments, which provide direct evidence on the C–I homolysis mechanism of 1avia 4-cyanopyridine-boryl radicals (see Fig. S5 and S6†). In addition, the intermediacy of the cross-coupling intermediate Int5-like as well as the by-product I-Bpin could be detected by the HRMS analysis of the reaction mixture of the perfluorobutyl, 4-cyanopyridine and 4-methylisopropenylbenzene 3a under the standard conditions (Scheme 4b, Fig. S7 and S8†). Finally, the addition of the perfluoroalkyl radical to alkenes could be further confirmed by a radical clock experiment using vinyl cyclopropane 3r as the substrate (see Fig. S9† for details). In combination, the studies revealed an unique strategy for the generation of perfluoroalkyl radicals and for subsequent perfluoroalkylative pyridylation of alkenes using the inexpensive 4-cyanopyridine/B2pin2 system.
Then, we examined the substrate scope of the carbon radical precursor with 4-methylisopropenylbenzene 3a as the radical acceptor (see Table 1). With perfluoroalkyl iodides (CnF2n+1–I), the corresponding α-perfluoroalkyl-β-pyridylation product could be obtained in moderate to good yields (4a–4e, 4g, 4i). Notably, the sterically congested substrate, perfluoro-isopropyl iodide, reacted smoothly to afford the desired product in moderate yield (4j, 45%). 1-Chlorotetrafluoro-2-iodoethane could also be converted into the desired product 4k in good yield via the selective cleavage of C–I bond. For the perfluoroalkyl bromides, the desired products (4f, 4h, 4l, 4m) could be formed in moderate yields under the standard conditions. The reaction of C6F13I, 4-cyanopyridine and alpha-methyl styrene on a 5 mmol scale in the presence of B2pin2 readily afforded 4e in 71% yield (1.8 g).
a Reaction conditions: 1 (0.2 mmol), B2(pin)2 (0.3 mmol), 4-cyanopyridine 2 (0.3 mmol), 4-methylisopropenylbenzene 3a (0.4 mmol), MTBE (1.0 mL), DIPEA (0.2 mmol), 24 h, 80 °C. Isolated yield. b 5 mmol scale. 1e (5 mmol), B2(pin)2 (7.5 mmol), 4-cyanopyridine (7.5 mmol), MTBE (15.0 mL), DIPEA (5.0 mmol), 24 h, 80 °C. Me = methyl, Et = ethyl.
Next, the substrate scope of alkenes was evaluated. As shown in Table 2, alpha-methyl styrene bearing a variety of functional groups (such as Br, MeS, CF3O, MeSO2, CN, CF3, CO2Me etc.) on the phenyl rings, were well compatible with this protocol, offering corresponding carbopyridylation products with quaternary carbon center (5aa–5as) in moderate to good yields (43–74%). Alpha-methyl naphthalenes also reacted to provide the desired products in good yields (5ba, 73% and 5bb, 70%). Furthermore, other alpha-methyl arylethene containing fused heterocycles, such as benzofuran, phenanthrene, fluorene and carbazole, could be converted into the corresponding products 5c–5f in moderate to good yields. The reactions of more sterically congested alpha-ethyl and -propyl styrenes provided the desired products (5ga–5h) in moderate yields. In addition, 1,1-disubstituted unactivated alkenes could also smoothly transform into the corresponding products (5i–5k, 45–54% yields). However, the reactions of methacrylate and 4-methoxystyrene only afforded the carbopyridylation products 5l and 5m in lower yields. With internal alkenes as substrates, no corresponding carbopyridylation products can be detected under standard conditions. Our DFT calculations suggest that the barrier heights for the addition of trifluoromethyl radical to internal alkene or terminal monosubstituted styrene are higher than that of disubstituted styrene by 1.2–3.4 kcal mol−1 (see Table S1†). This result may be responsible for the experimental facts described above. Thus, internal alkenes or terminal monodisubstituted styrenes are not suitable for the present transformation.
a Reaction conditions: 1a (0.2 mmol), B2(pin)2 (0.3 mmol), 4-cyanopyridine (0.3 mmol), alkene (0.4 mmol), MTBE (1.0 mL), DIPEA (0.2 mmol), 24 h, 80 °C. Isolated yield. Me = methyl, Et = ethyl, tBu = tert-butyl.
Both pyridine and perfluoroalkyl groups are prevalent motifs in drugs and natural products. The simultaneous incorporation of these two groups into bioactive molecules might improve their properties, such as reactivity and metabolic stability and selectivity.2,6 As illustrated in Table 2, four complicated alkene substrates derived from abietic acid, gemfibrozil, 1-adamantaneacetic acid, and cholesterol, readily underwent the carbopyridylation to give products 5n–5q in moderate to good yields.
In summary, we reported a metal- and photo-free synthetic method for perfluoroalkylative pyridylation of alkenes. Density functional theory calculations and control experiments indicate the in situ prepared 4-cyanopyridine-boryl radicals from 4-cyanopyridine and B2(pin)2, which not only activates the C–I bond homolysis but also serves as a pyridine precursor, play a key role in this transformation. A high functional group tolerance and broad substrate scope were achieved. This method provides a scalable and operationally simple protocol for difunctionalization of alkenes with inexpensive 4-cyanopyridine/B2(pin)2 reagents. We anticipated that the present approach would be useful for the construction of molecules with complexity and late stage modification of drugs and natural products.
This work was supported by the National Natural Science Foundation of China (Grants No. 21833002, No. 21673110, and No. 21572099), and China Postdoctoral Science Foundation (Grant No. 2017M620198). All calculations in this work have been done on the IBM Blade cluster system in the High Performance Computing Center of Nanjing University.
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