Microwave Irradiation: Alternative Heating Process for the Synthesis of Biologically Applicable Chromones, Quinolones, and Their Precursors

Microwave irradiation has become a popular heating technique in organic synthesis, mainly due to its short reaction times, solventless reactions, and, sometimes, higher yields. Additionally, microwave irradiation lowers energy consumption and, consequently, is ideal for optimization processes. Moreover, there is evidence that microwave irradiation can improve the regioselectivity and stereoselectivity aspects of vital importance in synthesizing bioactive compounds. These crucial features of microwave irradiation contribute to its inclusion in green chemistry procedures. Since 2003, the use of microwave-assisted organic synthesis has become common in our laboratory, making our group one of the first Portuguese research groups to implement this heating source in organic synthesis. Our achievements in the transformation of heterocyclic compounds, such as (E/Z)-3-styryl-4H-chromen-4-ones, (E)-3-(2-hydroxyphenyl)-4-styryl-1H-pyrazole, (E)-2-(4-arylbut-1-en-3-yn-1-yl)-4H-chromen-4-ones, or (E)-2-[2-(5-aryl-2-methyl-2H-1,2,3-triazol-4-yl)vinyl]-4H-chromen-4-ones, will be discussed in this review, highlighting the benefits of microwave irradiation use in organic synthesis.


Introduction
Organic synthesis, essential in producing new biologically active compounds, particularly for potential pharmaceutical use, is commonly associated with dangerous and toxic procedures, especially for the environment. As so, scientists are more and more focused on developing innovative environmentally friendly methodologies, following as much as possible the Green Chemistry Principles (GCP) [1,2]. In this context, although not consensual, microwave-assisted organic synthesis seems to be an excellent approach to fulfill some of the GCP [3][4][5]. The design for energy efficiency seems obvious, but safer solvents and auxiliaries and fewer derivatives' production are also achieved principles when microwave irradiation is employed. There are some shreds of evidence that microwave irradiation heating is achieved through the interaction of electromagnetic radiation at the molecular level, thereby producing the necessary energy to accomplish the reaction [6,7]. Additionally, it was established that in some reactions the electromagnetic wave effect is involved in the electron transfer process [8]. Moreover, there is evidence that microwave irradiation use is very efficient in synthesizing heterocyclic compounds, making it an essential heating source in developing new potential drugs [9]. One of the main focuses of our research group is the synthesis of both oxygen and nitrogen heterocyclic compounds, being the foremost examples of this kind of heterocycles, chromone, and quinolone derivatives. These heterocycles are often found in market drugs such as pranlukast and gatifloxacin (Figure 1), used to treat allergic rhinitis and as antibacterial agents, respectively [10,11].
Given that microwave irradiation was established in our research group, it is now a common energy source in our daily laboratory work, aiming to obtain new bioactive compounds in fewer minutes, using less amounts of solvents, and getting fewer by-products. In this review, we discuss the most noticeable features obtained in some common transformations by using microwave irradiation, highlighting the type of heterocyclic compounds obtained and, when possible, the effect of microwave irradiation on the transformation stereochemistry.

Microwave-Assisted Aldol Condensation in the Synthesis of Chalcones
The aldol condensation is one of the most valuable strategies to form carbon-carbon bonds, apparently was first introduced in 1872 by Charles Wurtz, and consists of the condensation of two carbonyl compounds (ketones or aldehyde) in the presence of an acid or a base as a catalyst [12,13]. This condensation is of particular application in the synthesis of chalcones, recognized bioactive flavonoids [14] and important precursors of chromones and quinolones. Our experience in their synthesis [15,16] indicates that the best results are obtained with base catalysis and usually a long reaction time (3 h to 20 h). Therefore, aiming to shorten the reaction time, we tested the aldol condensation of 2 -hydroxyacetophenones 1 with benzaldehydes 2 under microwave irradiation (Scheme 1) [17]. and gatifloxacin (Figure 1), used to treat allergic rhinitis and as antibacterial agents, respectively [10,11]. Given that microwave irradiation was established in our research group, it is now a common energy source in our daily laboratory work, aiming to obtain new bioactive compounds in fewer minutes, using less amounts of solvents, and getting fewer by-products. In this review, we discuss the most noticeable features obtained in some common transformations by using microwave irradiation, highlighting the type of heterocyclic compounds obtained and, when possible, the effect of microwave irradiation on the transformation stereochemistry.

Microwave-Assisted Aldol Condensation in the Synthesis of Chalcones
The aldol condensation is one of the most valuable strategies to form carbon-carbon bonds, apparently was first introduced in 1872 by Charles Wurtz, and consists of the condensation of two carbonyl compounds (ketones or aldehyde) in the presence of an acid or a base as a catalyst [12,13]. This condensation is of particular application in the synthesis of chalcones, recognized bioactive flavonoids [14] and important precursors of chromones and quinolones. Our experience in their synthesis [15,16] indicates that the best results are obtained with base catalysis and usually a long reaction time (3 h to 20 h). Therefore, aiming to shorten the reaction time, we tested the aldol condensation of 2′-hydroxyacetophenones 1 with benzaldehydes 2 under microwave irradiation (Scheme 1) [17]. We should highlight a few points concerning the methodology. Obviously, the achieved objective was shortening the reaction time to 15 min when 2′-hydroxyacetophenone was used and to 20 min for the 2′-aminoacetophenone. The yields were excellent for both electron-donating and -withdrawn groups, and the procedure is straightforward: We can apply it in an undergraduate organic synthesis laboratory. Furthermore, it is possible to scale up to 500 g if it is used as a Milestone-MicroSynth with several vessels.

Microwave-Induced Baker-Venkataraman Rearrangement for the Synthesis of Chromones
Chromones (4H-chromen-4-ones) and the corresponding nitrogen analogues, quinolones (quinolin-4(1H)-one), are recognized for their vast biological activity [11,18], a fact that also encourages their synthesis. The Baker-Venkataraman rearrangement is one of the oldest methodologies to obtain chromone derivatives [19], and we established some modifications that simplify the procedures [20,21]. However, in classical heating conditions, the reaction time is always long, 1 or more hours, and sometimes more than one Scheme 1. Synthesis of chalcones using a Milestone-MicroSynth.
We should highlight a few points concerning the methodology. Obviously, the achieved objective was shortening the reaction time to 15 min when 2 -hydroxyacetophenone was used and to 20 min for the 2 -aminoacetophenone. The yields were excellent for both electron-donating and -withdrawn groups, and the procedure is straightforward: We can apply it in an undergraduate organic synthesis laboratory. Furthermore, it is possible to scale up to 500 g if it is used as a Milestone-MicroSynth with several vessels.

Microwave-Induced Baker-Venkataraman Rearrangement for the Synthesis of Chromones
Chromones (4H-chromen-4-ones) and the corresponding nitrogen analogues, quinolones (quinolin-4(1H)-one), are recognized for their vast biological activity [11,18], a fact that also encourages their synthesis. The Baker-Venkataraman rearrangement is one of the oldest methodologies to obtain chromone derivatives [19], and we established some modifications that simplify the procedures [20,21]. However, in classical heating conditions, the reaction time is always long, 1 or more hours, and sometimes more than one product is obtained [21]. Therefore, the use of microwave irradiation to perform the transformation seemed to be a good approach to shortening the reaction time and simultaneously using a greener energy source. In that regard, both 3-aroyl-2-aryl-4H-chromen-4-ones (5, R = C 6 H 5 ) and 3-cinnamoyl-2-[(E)-styryl]-4H-chromen-4-ones (5, R = CHCHC 6 H 5 ) were obtained with yields above 60% (Scheme 2) [22,23]. The main achievement of these transformations using microwave irradiation was the reduced reaction time and the scale-up to nearly 1 kg, using several vessels simultaneously. Still, the fact that the reaction does not need a nitrogen atmosphere is also important because it reduces its cost. product is obtained [21]. Therefore, the use of microwave irradiation to perform the transformation seemed to be a good approach to shortening the reaction time and simultaneously using a greener energy source. In that regard, both 3-aroyl-2-aryl-4H-chromen-4ones (5, R = C6H5) and 3-cinnamoyl-2-[(E)-styryl]-4H-chromen-4-ones (5, R = CHCHC6H5) were obtained with yields above 60% (Scheme 2) [22,23]. The main achievement of these transformations using microwave irradiation was the reduced reaction time and the scaleup to nearly 1 kg, using several vessels simultaneously. Still, the fact that the reaction does not need a nitrogen atmosphere is also important because it reduces its cost. Scheme 2. Synthesis of 3-aroyl-and 3-cinnamoyl-4H-chromen-4-ones using a Milestone-Micro-Synth.
A similar procedure was used to shorten the reaction time of the (E)-2-styrylquinolin-4(1H)-ones 7 synthesis through a one-pot process involving the cinnamoyl transposition and cyclization (Scheme 3) [24]. We achieved the desired reduced reaction time, and the developed methodology, under microwave irradiation, which had two extra positive effects: the use of a less dangerous base and the possibility to obtain, although in lower yield (25%), the (E)-2-(4-nitrostyryl)quinolin-4(1H)-one, which is not obtained in classical heating conditions [24]. Scheme 3. Synthesis of (E)-2-styrylquinolin-4(1H)-ones using a Milestone-MicroSynth.

Microwave-Assisted Knoevenagel Condensation in 3-Styryl-4H-Chromen-4-Ones Synthesis
Knoevenagel condensation, a reaction named after being established by the German chemist Emil Knoevenagel [25][26][27], is commonly used in organic synthesis and is of particular utility in total synthesis [28]. In our case, we applied this type of reaction to obtain chromone derivatives, in particular (E)-3-styryl-4H-chromen-4-ones 10 [29]. The methodology consists of the Knoevenagel condensation between the 4H-chromen-4-one-3-carbaldehyde 8 with arylacetic acids 9, followed by an in situ decarboxylation (Scheme 4). A similar procedure was used to shorten the reaction time of the (E)-2-styrylquinolin-4(1H)-ones 7 synthesis through a one-pot process involving the cinnamoyl transposition and cyclization (Scheme 3) [24]. We achieved the desired reduced reaction time, and the developed methodology, under microwave irradiation, which had two extra positive effects: the use of a less dangerous base and the possibility to obtain, although in lower yield (25%), the (E)-2-(4-nitrostyryl)quinolin-4(1H)-one, which is not obtained in classical heating conditions [24]. product is obtained [21]. Therefore, the use of microwave irradiation to perform the transformation seemed to be a good approach to shortening the reaction time and simultaneously using a greener energy source. In that regard, both 3-aroyl-2-aryl-4H-chromen-4ones (5, R = C6H5) and 3-cinnamoyl-2-[(E)-styryl]-4H-chromen-4-ones (5, R = CHCHC6H5) were obtained with yields above 60% (Scheme 2) [22,23]. The main achievement of these transformations using microwave irradiation was the reduced reaction time and the scaleup to nearly 1 kg, using several vessels simultaneously. Still, the fact that the reaction does not need a nitrogen atmosphere is also important because it reduces its cost.
A similar procedure was used to shorten the reaction time of the (E)-2-styrylquinolin-4(1H)-ones 7 synthesis through a one-pot process involving the cinnamoyl transposition and cyclization (Scheme 3) [24]. We achieved the desired reduced reaction time, and the developed methodology, under microwave irradiation, which had two extra positive effects: the use of a less dangerous base and the possibility to obtain, although in lower yield (25%), the (E)-2-(4-nitrostyryl)quinolin-4(1H)-one, which is not obtained in classical heating conditions [24].
A similar procedure was used to shorten the reaction time of the (E)-2-styrylquinolin-4(1H)-ones 7 synthesis through a one-pot process involving the cinnamoyl transposition and cyclization (Scheme 3) [24]. We achieved the desired reduced reaction time, and the developed methodology, under microwave irradiation, which had two extra positive effects: the use of a less dangerous base and the possibility to obtain, although in lower yield (25%), the (E)-2-(4-nitrostyryl)quinolin-4(1H)-one, which is not obtained in classical heating conditions [24].
4H-Chromen-4-one-3-carbaldehydes condensation with phenylmalonic acid was also performed under microwave irradiation (120 W) at 100 • C for 7 min [31]. The yields were slightly lower (from 47% to 61%), and the diastereoselectivity towards (E)-isomer was maintained. Additionally, the reaction was performed in solid support, the sodium acetate, adding an additional greener effect to this procedure, eliminating a solvent.

Microwave-Induced Heck Reaction towards the Synthesis of (E)-3-styrylflavones and (E)-3-styrylquinolin-4(1H)-ones
In 1972, Heck and Nolley reported a halide-olefinic substitution catalyzed by palladium catalysis [32]. Since then, not only the reaction is generally called Heck reaction but also proved to be suitable in the synthesis of several organic compounds [33,34], including natural products [35] and more complex molecules [36].
model Discover SP.
The use of microwave irradiation profit was the massive cut in the reaction time, from 12 h to 31 h in classical heating conditions to 1 h under microwave conditions [29]. Moreover, it was observed that the presence of a nitro group in the para position of the arylacetic acid 9 lowers the yield of the corresponding (E)-3-styryl-4H-chromen-4-ones 10, both in classic (48%) and microwave conditions (56%), with the microwave improving the yield slightly. Later on, we applied the methodology successfully to different 4Hchromen-4-one-3-carbaldehyde derivatives 8. Although the (E)-5-methoxy-3-styryl-4Hchromen-4-one obtained 37%, the method seems to be efficient and, above all, diastereoselective to prepare the (E)-isomer (Scheme 4) [30].
4H-Chromen-4-one-3-carbaldehydes condensation with phenylmalonic acid was also performed under microwave irradiation (120 W) at 100 °C for 7 min [31]. The yields were slightly lower (from 47% to 61%), and the diastereoselectivity towards (E)-isomer was maintained. Additionally, the reaction was performed in solid support, the sodium acetate, adding an additional greener effect to this procedure, eliminating a solvent.

Microwave-Induced Heck Reaction towards the Synthesis of (E)-3-Styrylflavones and (E)-3-Styrylquinolin-4(1H)-Ones
In 1972, Heck and Nolley reported a halide-olefinic substitution catalyzed by palladium catalysis [32]. Since then, not only the reaction is generally called Heck reaction but also proved to be suitable in the synthesis of several organic compounds [33,34], including natural products [35] and more complex molecules [36].

Scheme 5. (A) Synthesis of (E)-3-styrylflavones; (B) synthesis of (E)-3-styrylquinolin-4(1H)-ones using a Milestone-MicroSynth.
The 3-Bromoflavones 11, although suitable substrates for Heck reaction with styrene derivatives, have some steric hindrance, which can explain the lower yields obtained in the experiments performed at classical heating conditions. Such disadvantages could be overcome using microwave irradiation as a heating source. The yields were much better Scheme 5. (A) Synthesis of (E)-3-styrylflavones; (B) synthesis of (E)-3-styrylquinolin-4(1H)-ones using a Milestone-MicroSynth. The 3-Bromoflavones 11, although suitable substrates for Heck reaction with styrene derivatives, have some steric hindrance, which can explain the lower yields obtained in the experiments performed at classical heating conditions. Such disadvantages could be overcome using microwave irradiation as a heating source. The yields were much better and the reaction was also accomplished in less than 10 min (Scheme 5A). Additionally, the presence of electron-withdrawing or -donating groups in the flavone B-ring did not prevent the transformation, and some interesting derivatives could also be obtained [39]. Another important feature of the developed methodology is its stereoselectivity. The obtained (E)-3-styrylflavones 13 presents the (E)-configuration of the vinylic system and the s-cis stereochemistry, as depicted in structure 13. NMR data can confirm both configurations, particularly the vinylic system coupling constant J = 17 Hz, typical of an (E)-configuration and the high chemical shift of the β-proton due to the anisotropic carbonyl deshielding [38]. We also extended our interest in this transformation to the use of 2-aryl-3-iodo-1methylquinolin-4(1H)-ones 14, which allowed the synthesis of (E)-3-styrylquinolin-4(1H)ones (15) in good yields (Scheme 5B) [39]. Naturally, the reaction conditions needed to be revised to these derivatives, mostly due to the 2-aryl-3-iodo-1-methylquinolin-4(1H)-ones 14 solubility and reactivity; but, overall, the results were excellent. We can highlight that the reaction time was short, and the product was again obtained with high stereoselectivity.

Diels-Alder Reactions Using 4H-chromen-4-ones and Quinolin-4(1H)-ones as Dienes
In 1928 Otto Diels and his student Kurt Alder published their first paper concerning a cycloaddition reaction that henceforth is known as the Diels-Alder (DA) reaction [40], among the most significant and adaptable reactions known in organic synthesis [41][42][43][44]. Notably, we initiated our interest in MW-assisted organic synthesis with a DA-reaction, delivering in 2003 the first literature report of MW-assisted DA reaction using 3-styrylquinolin-4(1H)-ones as substrates [45]. Since then, our research group has kept its interest in developing MW-assisted methods for synthesizing a diversity of compounds based on both inter-and intramolecular DA reactions.
tained (E)-3-styrylflavones 13 presents the (E)-configuration of the vinylic system and the s-cis stereochemistry, as depicted in structure 13. NMR data can confirm both configurations, particularly the vinylic system coupling constant J = 17 Hz, typical of an (E)-configuration and the high chemical shift of the β-proton due to the anisotropic carbonyl deshielding [38].
We also extended our interest in this transformation to the use of 2-aryl-3-iodo-1methylquinolin-4(1H)-ones 14, which allowed the synthesis of (E)-3-styrylquinolin-4(1H)ones (15) in good yields (Scheme 5B) [39]. Naturally, the reaction conditions needed to be revised to these derivatives, mostly due to the 2-aryl-3-iodo-1-methylquinolin-4(1H)-ones 14 solubility and reactivity; but, overall, the results were excellent. We can highlight that the reaction time was short, and the product was again obtained with high stereoselectivity.

Diels-Alder Reactions Using 4H-Chromen-4-Ones and Quinolin-4(1H)-Ones as Dienes
In 1928 Otto Diels and his student Kurt Alder published their first paper concerning a cycloaddition reaction that henceforth is known as the Diels-Alder (DA) reaction [40], among the most significant and adaptable reactions known in organic synthesis [41][42][43][44]. Notably, we initiated our interest in MW-assisted organic synthesis with a DA-reaction, delivering in 2003 the first literature report of MW-assisted DA reaction using 3-styrylquinolin-4(1H)-ones as substrates [45]. Since then, our research group has kept its interest in developing MW-assisted methods for synthesizing a diversity of compounds based on both inter-and intramolecular DA reactions.
Considering the reaction with the dienophiles 17 and 18, besides the good reaction yields, it is noteworthy the stereoselectivity of the reaction towards the endo cycloadduct is depicted in structure 20 (Scheme 6). This result was also supported by ab initio calculations, which showed that the thermodynamically controlled product was formed [47].
Considering the reaction with the dienophiles 17 and 18, besides the good reaction yields, it is noteworthy the stereoselectivity of the reaction towards the endo cycloadduct is depicted in structure 20 (Scheme 6). This result was also supported by ab initio calculations, which showed that the thermodynamically controlled product was formed [47]. Remarkably, the exo cycloadduct 22 can be obtained in the DA reaction using (E)-3-styryl-4H-chromen-4-ones 10 as dienes (Scheme 7) [45,47]. Following these earlier studies in DA reactions with (E)-and (Z)-3-styryl-4Hchromen-4-ones as dienes, years later, we also explored the reactivity of particular chromone derivatives 23 and 25 to develop a method for the synthesis of 9H-xanthen-9-one-1,2,3-triazole hybrids 27 (Scheme 8) [48]. The diene of chromones 23 showed very low reactivity in classical heating conditions using maleimides as dienophiles. Fortunately, when multimode MW irradiation was applied, cycloadducts 24 were obtained in 20-30% yield in 20-min reaction time (Scheme 8A). Using a monomode microwave apparatus, we further improved the reaction yield to 31-45%, shortening the reaction time from 20 min to 10 min and avoiding the use of solvents (Scheme 8). The same principle was applied to chromone derivatives 25 (1,2,3-triazole replacing the internal alkyne of chromones 23), and again the best yields of cycloadducts 26 (36-48%) were achieved after 10 min of monomode MW irradiation, in solvent-free conditions (Scheme 8B). Following these earlier studies in DA reactions with (E)-and (Z)-3-styryl-4H-chromen-4-ones as dienes, years later, we also explored the reactivity of particular chromone derivatives 23 and 25 to develop a method for the synthesis of 9H-xanthen-9-one-1,2,3-triazole hybrids 27 (Scheme 8) [48]. The diene of chromones 23 showed very low reactivity in classical heating conditions using maleimides as dienophiles. Fortunately, when multimode MW irradiation was applied, cycloadducts 24 were obtained in 20-30% yield in 20-min reaction time (Scheme 8A). Using a monomode microwave apparatus, we further improved the reaction yield to 31-45%, shortening the reaction time from 20 min to 10 min and avoiding the use of solvents (Scheme 8). The same principle was applied to chromone derivatives 25 (1,2,3-triazole replacing the internal alkyne of chromones 23), and again the best yields of cycloadducts 26 (36-48%) were achieved after 10 min of monomode MW irradiation, in solvent-free conditions (Scheme 8B). Following these studies, we decided to replace the internal alkyne of chromones 23 for an additional double bond to came up with 4H-chromen-4-one compounds with two dienes 28 (Scheme 9) [49]. This particular type of compound has two possible DA reaction sites, the reactivity of which was further explored using MW irradiation. If Sc(OTf)3 is used as Lewis acid in the solvent-free DA reaction of 4H-chromen-4-ones 28 with Nmethylmaleimide, monoadducts 29 are obtained in 52-77% yield (Scheme 9). On the other hand, in the absence of this Lewis acid, it was possible to drive the DA reaction towards the bisadduct 30 in 60% yield, obtained as a mixture of two diastereomers (Scheme 9). Following these studies, we decided to replace the internal alkyne of chromones 23 for an additional double bond to came up with 4H-chromen-4-one compounds with two dienes 28 (Scheme 9) [49]. This particular type of compound has two possible DA reaction sites, the reactivity of which was further explored using MW irradiation. If Sc(OTf) 3 is used as Lewis acid in the solvent-free DA reaction of 4H-chromen-4-ones 28 with Nmethylmaleimide, monoadducts 29 are obtained in 52-77% yield (Scheme 9). On the other hand, in the absence of this Lewis acid, it was possible to drive the DA reaction towards the bisadduct 30 in 60% yield, obtained as a mixture of two diastereomers (Scheme 9).
This intramolecular DA methodology allowed the efficient synthesis of a family of chromeno[3,4-b]-9H-xanthen-9-ones, a very interesting scaffold to develop multi-target drugs for Alzheimer disease [56]. This type of compound has a hybrid structure featuring the 9H-xanthen-9-one and chromene pharmacophoric units, with demonstrated anticholinesterase potency in the low-micromolar range (2.1 to 6.9 µM) and the ability to inhibit the amyloid-β (Aβ) 1-42 self-aggregation up to 70% (Figure 2). Docking studies allowed us to propose a binding mode for chromeno [3,4-b]-9H-xanthen-9-ones against acetylcholinesterase (AChE), grounded on the role of Ser203 and Phe294, which formed hydrogen-bonding interactions with the heterocyclic rings. The chromeno[3,4b]-9H-xanthen-9-ones binding was stabilized by several π-stacking interactions between the main scaffold and aromatic residues in the binding pocket Trp86, Trp286, Phe338, and Tyr341. The slight differences in the binding affinity were probably due to the cost of the methoxy accommodation, resulting in small re-adjustments of the residues of the binding pocket. This explains why the unsubstituted derivative, which perfectly formed three π-stacking interactions and two hydrogen bonds, was the best compound exploited among all (Figure 2). Both experimental and computational insights allowed us to develop two lead compounds, depending on if the final goal was a single-target or a dual-target compound ( Figure 2). Furthermore, we would like to highlight that chromeno[3,4-b]-9Hxanthen-9-ones are first-in-class AChE and Aβ aggregation dual inhibitors [56].
The interest of our research group in MW-assisted DA reactions for the synthesis of heterocycles dates back to 2003. However, the intramolecular version of the DA reaction using 4H-chromen-4-one derivatives was only reported 15 years later [55], with the synthesis of 2-(benzo[c]chromenyl)-4H-chromen-4-ones 41 and chromeno[3,4-b]-9H-xanthen-9-ones 42 in 78-85% and 75-82% yield, respectively, through intramolecular DA reaction followed by chloranil-mediated aromatization of O-propargyl 4H-chromen-4-ones with distinct unsaturated π-systems 39 and 40 (Scheme 13) [55]. This intramolecular DA methodology allowed the efficient synthesis of a family of chromeno[3,4-b]-9H-xanthen-9-ones, a very interesting scaffold to develop multi-target drugs for Alzheimer disease [56]. This type of compound has a hybrid structure featuring the 9H-xanthen-9-one and chromene pharmacophoric units, with demonstrated anticholinesterase potency in the low-micromolar range (2.1 to 6.9 μM) and the ability to inhibit the amyloid-β (Aβ) 1-42 self-aggregation up to 70% (Figure 2). Docking studies allowed us to propose a binding mode for chromeno [3,4-b]-9H-xanthen-9-ones against acetylcholinesterase (AChE), grounded on the role of Ser203 and Phe294, which formed hydrogenbonding interactions with the heterocyclic rings. The chromeno [3,4-b]-9H-xanthen-9-ones binding was stabilized by several π-stacking interactions between the main scaffold and aromatic residues in the binding pocket Trp86, Trp286, Phe338, and Tyr341. The slight differences in the binding affinity were probably due to the cost of the methoxy accommodation, resulting in small re-adjustments of the residues of the binding pocket. This explains why the unsubstituted derivative, which perfectly formed three π-stacking interactions and two hydrogen bonds, was the best compound exploited among all (Figure 2). Both experimental and computational insights allowed us to develop two lead compounds, depending on if the final goal was a single-target or a dual-target compound

Tandem Reactions towards the Synthesis of Oxygen Polycyclic Compounds
The synthesis of oxygen polycyclic benzo [1,3]

Tandem Reactions towards the Synthesis of Oxygen Polycyclic Compounds
The synthesis of oxygen polycyclic benzo [1,3]cyclopropa [1,2-b]chromene-4,5-diones 44 involved the microwave-assisted reaction of 3-bromo-2-styryl-4H-chromen-4-ones 43 with 1-(prop-1-en-2-yl)pyrrolidine (generated in situ by the reaction of acetone with pyrrolidine) (Scheme 14) [57]. Under classical heating conditions, the polycyclic structure 44 was obtained after a 7h reaction time. When this reaction was performed under microwave-irradiation conditions, we were able to decrease the reaction time to 20 min and, consequently, get a cleaner reaction mixture, which allowed us to fully characterize the complex diastereomeric mixture (Scheme 14, inset) of benzo [1,3] Under classical heating conditions, the polycyclic structure 44 was obtained after a 7-h reaction time. When this reaction was performed under microwave-irradiation conditions, we were able to decrease the reaction time to 20 min and, consequently, get a cleaner reaction mixture, which allowed us to fully characterize the complex diastereomeric mixture (Scheme 14, inset) of benzo [1,3]cyclopropa [1,2-b]chromene-4,5-diones 44 by NMR techniques [57]. The proposed mechanism for forming these fused polycyclic compounds 44 consisted of a tandem sequence of 1,6-conjugate addition, Michael-initiated ring closure, and imine hydrolysis. It is noteworthy that this cascade process was fueled by its high efficiency in producing three new C-C bonds and four new stereocenters, one of them a quaternary carbon, in one single operation.
Steroidal compounds are widely present in living organisms, playing important roles in their vital activities [58]. The most recognizable steroidal compound is cholesterol (cholest-5-en-3β-ol), which is considered a lipid-type molecule, being one of the most important structural components of cell membranes [59,60]. Following our ongoing interest in modified steroidal compounds for biological purposes, such as protein aggregation inhibitors, we used the MW-assisted regioselective synthesis of cholestane-fused compounds 46 and 47 (Scheme 15) [61]. In classical heating conditions, the reaction of α,β-unsaturated carbonyl substrates 45 with malononitrile is difficult to control, leading to complex reaction mixtures of several unidentified compounds. Upon application of MW irradiation, we managed to drive the reaction in different directions, carefully controlling the amount of malononitrile. This strategy allowed the efficient synthesis of pyran-46 and 2-aminoisophthalonitrile-cholestane 47-fused compounds, in 65-83% and 30-37% yield, respectively (Scheme 15) [61]. pounds 46 and 47 (Scheme 15) [61]. In classical heating conditions, the reaction of α,βunsaturated carbonyl substrates 45 with malononitrile is difficult to control, leading to complex reaction mixtures of several unidentified compounds. Upon application of MW irradiation, we managed to drive the reaction in different directions, carefully controlling the amount of malononitrile. This strategy allowed the efficient synthesis of pyran-46 and 2-aminoisophthalonitrile-cholestane 47-fused compounds, in 65-83% and 30-37% yield, respectively (Scheme 15) [61].

Miscellaneous Reactions
Among other types of reactions developed under microwave-assisted conditions, we would like to highlight the 2′-aminochalcone cyclization [17] and the oxidative aromatization [47,53,62,63] due to their importance in the synthesis of new potential bioactive heterocycles.
Bearing in mind that in Nature 2′-hydroxychalcones isomerize by a ring closure into flavanones, we studied the 2′-aminochalcones 3 isomerization into azaflavanones 48, the 2-aryl-2,3-dihydroquinolin-4(1H)-ones (Scheme 16) [17]. Our study established a straightforward procedure using the solid support montmorillonite K10 and microwave irradiation to induce cyclization in very good yields and short reaction time. Furthermore, the desired product was obtained by removing the solid support (Scheme 16) [17].

Miscellaneous Reactions
Among other types of reactions developed under microwave-assisted conditions, we would like to highlight the 2 -aminochalcone cyclization [17] and the oxidative aromatization [47,53,62,63] due to their importance in the synthesis of new potential bioactive heterocycles.

Conclusions
Microwave irradiation has become a widely used heating technique in organic synthesis, and our research group is no exception. Our interest in microwave-assisted synthesis has lasted almost 20 years. Over this time, our group synthesized a variety of nitrogen-and oxygen-heterocycles, resorting to this amazing heating strategy. Our experience showed us that microwave heating is a powerful tool to shorten reactions' times from days to a few hours or even minutes. This is perhaps the main advantage that we took from using microwave irradiation. However, in a few cases, we could manage to "clean up" extremely sluggish reaction mixtures beyond the reduction of reaction time, which helped us understand complex structures and reaction mechanisms. Such features of microwaves are not often mentioned in literature reports, which mainly focus on the reduction of reaction times and improvement of the reaction yields. Another important "green" feature is that by resorting to focused microwave irradiation, it is possible to avoid using solvents, some of them highly toxic both for human health and the environment. Finally, we should not forget that microwaves also allowed us to synthesize promising dual-target compounds for Alzheimer disease, otherwise extremely difficult to obtain in appreciable amounts by classical heating conditions.