1. Introduction
In recent years, organoselenium compounds have shown extensive academic interest because of their broad biological activity, just as pharmacological actions [
1]. An important example of this class of compounds is ebselen (
Figure 1), which recently stood out as being promising, among 10,000 substances studied, in the treatment against COVID-19 [
2]. Among organoselenium compounds, a class of di- and tri selenide alkene derivatives have received great attention in recent decades, due to their chemical properties and also, great pharmaceutical potential [
3]. In addition, the interest in the chemistry of bis-vinyl-selenides has increased since their important functionality was discovered as valuable intermediates, with considerable synthetic application. Thus, there are numerous advantages for this class of compounds, and among them can be highlighted its potential in synthetic applications. The diverse applicability of this type of molecules can be explained by the fact that the calcogen atom exerts a stabilizing effect on positive or negative neighboring charges that makes the double bond in vinyl chalcogenides susceptible of both nucleophilic and electrophilic attacks, an extremely useful resource for organic synthetic purposes.
However, despite the fact that bis-vinyl-seleides compounds are very promising in biological and synthetic aspects, the methods applied until now for their synthesis are considerably outdated and aggressive from an environmental point of view As can be seen in
Scheme 1, obtaining this type of structure was carried out through a methodology with several disadvantages, such as the use of toxic solvents, reagents, heavy metals and long reaction times [
4,
5,
6].
Therefore, due to the importance of this class of organoselenium compounds, there is a growing need for the development of environmentally accepted protocols. In this work, a new environmentally friendly methodology is proposed for the synthesis of bis-selenide-alkene derivatives using the green catalytic system I2/DMSO.
2. Methods
General procedure for the synthesis of bis-selenide-alkene derivatives. In a specific microwave glass tube (10 mL) equipped with a magnetic stir bar, diphenylacetylene (0.125 mmol), diphenyl diselenide (1 eq), I2 (30 mol%) and DMSO (2 eq) were added. Then, the tube was sealed with an appropriate cap and the reaction mixture was placed in the microwave reactor, in a closed system, and the power conditions (100 W), temperature (100 °C), time (20 min) and heating ramp (1 min) were adjusted. The reaction system was irradiated at maximum power until reaching the programmed temperature, for 20 min. After reaching the programmed temperature, the device was adjusted to keep the temperature constant. After the completion of the reaction, 5 mL of ethyl acetate (AcOEt) was added and the reaction mixture was washed with 10% Na2S2O4 solution. The crude product was purified by preparative plate, eluting with a hexane.
Characterization. 1,4-diphenylethyne (Compound 3). 0.027 g, yield: 82%, brown-yellow white oil, 1H NMR (500 MHz, CDCl3) δ 7.98 (d, J = 10 Hz, 1H), 7.66 (t, J = 5 Hz, 10H), 7.51 (t, J = 5 Hz, 10H)).
3. Results and Discussion
According to the objectives proposed for this work, the reaction between diphenylacetylene (1) and (PhSe)
2 (2) was used as a standard reagent to optimize the reaction parameters. As observed in the results shown in
Table 1, the first reaction with 1 eq of (2), 1 eq DMSO, 10 mol% of I
2 was performed under conventional heating at 100 °C for 24 h. In this condition, the desired product 3 was obtained in 20% of yield (
Table 1, entry 1). Then, the reaction time was increased and the bis-selenide-alkene (3) was achieved only in 15% of yield (
Table 1, entry 2). Using the same quantities of the reagents and the same temperature, the reaction was performed under microwave irradiation during 20 min and the yield obtained was 17% (
Table 1, entry 3). In entries 3 and 4, when the amounts of iodine and DMSO were varied, there was an increase in the yield. Encouraged by this result, the next parameter analyzed was the (PhSe)
2 (2) equivalents and to our convenience, according to entry 6, 0.55 eq of (2) caused a jump in the reaction yield with a value of 82%. Then, a shorter reaction time was evaluated and the product formed with 70% yield.
As an example, the product of interest (
3) was characterized by the analysis of hydrogen nuclear magnetic resonance (500 MHz, CDCl
3). In this spectrum shown in
Figure 2, it is possible to observe at 7.98 ppm the presence of a double (J = 10 Hz) sign with an integral relative to eight aromatic hydrogens. At 7.66 ppm, there is a triplet (J = 5, 10 Hz) with an integral relative to four aromatic hydrogens. Finally, at 7.52 ppm is located another triplet (J = 5 Hz, 10 Hz) referring to the other eight aromatic hydrogens that make up the molecule, i.e., the total the expected hydrogens for the molecule.
It is important to highlight that this work remains in progress. It will be necessary to evaluate more reaction parameters, such as the reaction time, to have the condition optimized. However, since March, to date it has not been possible to proceed due to the arrival of the COVID-19 pandemic and the suspension of the laboratory activities in the University.
4. Conclusions and Perspectives
The present work has shown, to date, that the methodology is being optimized in an effective and satisfactory way, enabling the formation of the desired bis-selenide-alkene 3 in a high yield (82%). The methodology follows the principles of green chemistry without using solvent, heavy metals and long reaction times. As soon as it is possible to return to post-pandemic activities, it is intended to proceed with the optimization steps by increasingly varying the diselenide equivalents, DMSO as well as the reaction temperature and time. Therefore, after the establishment of an optimized methodology, the reaction scope will be evaluated using different substituted diselenides and even disulfides or ditellurides.