A Comprehensive Review of Aminochalcones

Chalcones, members of the flavonoid family, display a plethora of interesting biological activities including but not limited to antioxidant, anticancer, antimicrobial, anti-inflammatory, and antiprotozoal activities. The literature cites the synthesis and activity of a range of natural, semisynthetic, and synthetic chalcones. The current review comprehensively covers the literature on amino-substituted chalcones and includes chalcones with amino-groups at various positions on the aromatic rings as well as those with amino-groups containing mono alkylation, dialkylation, alkenylation, acylation, and sulfonylation. The aminochalcones are categorized according to their structure, and the corresponding biological activities are discussed as well. Some compounds showed high potency against cancer cells, microbes, and malaria, whereas others did not. The purpose of this review is to serve as a one-stop location for information on the aminochalcones reported in the literature in recent years.


Introduction
The (E)-1,3-diphenyl-2-propene-1-one scaffold, also known as "chalcone" is not only a key structure for synthetic manipulations but also a constituent of many natural products. Chalcones are considered precursors of flavonoids and isoflavones and can act as synthons for a range of heterocycles with pharmaceutical importance [1][2][3]. The chemical structure of a chalcone consists of two aromatic rings on either side of an α, ß-unsaturated carbonyl system ( Figure 1).

Introduction
The (E)-1,3-diphenyl-2-propene-1-one scaffold, also known as "chalcone" is not only a key structure for synthetic manipulations but also a constituent of many natural products. Chalcones are considered precursors of flavonoids and isoflavones and can act as synthons for a range of heterocycles with pharmaceutical importance [1][2][3]. The chemical structure of a chalcone consists of two aromatic rings on either side of an α, ß-unsaturated carbonyl system ( Figure 1). The most common method to synthesize chalcones is the Claisen-Schmidt condensation method, which uses either base or acid-catalyzed condensation of the aldehyde and ketone, that is typically followed by in situ dehydration (Scheme 1). The most common method to synthesize chalcones is the Claisen-Schmidt condensation method, which uses either base or acid-catalyzed condensation of the aldehyde and ketone, that is typically followed by in situ dehydration (Scheme 1). Scheme 1. General scheme for the synthesis of chalcone.
Aminochalcones constitute an important class of chalcones that contain an -NR2 group on either ring A or ring B of the chalcone ( Figure 2). These compounds have been synthesized and evaluated for their biological significance by various groups recently. The cytotoxic activity of aminochalcones has been an area of interest due to the possibility of an enhanced electrophilic attack on cellular proteins through hetero-Michael addition leading to a covalent bond. The covalent inhibitors are an emerging area of drug discovery, and the aminochalcones hold the potential to serve as leads for the development of inhibitors targeting specific cellular proteins. R, R': NH2, NX2, NXH The purpose of this review article is to summarize and list the aminochalcones reported in the literature. We aim to list the developments and pharmacological significance of aminochalcones by presenting a comprehensive list of the compounds with their significant biological activities. To understand the structure-activity relationship of aminochalcones, we will be categorizing these by the substitution position of the amino-group on both rings. Other categories will include N-alkyl, Nalkenyl, N-acyl, and N-sulfonyl aminochalcones. Thus the article will provide the versatile biological activities of aminochalcones and their relationship with the structure.
Aminochalcones constitute an important class of chalcones that contain an -NR 2 group on either ring A or ring B of the chalcone ( Figure 2). These compounds have been synthesized and evaluated for their biological significance by various groups recently. The cytotoxic activity of aminochalcones has been an area of interest due to the possibility of an enhanced electrophilic attack on cellular proteins through hetero-Michael addition leading to a covalent bond. The covalent inhibitors are an emerging area of drug discovery, and the aminochalcones hold the potential to serve as leads for the development of inhibitors targeting specific cellular proteins. The purpose of this review article is to summarize and list the aminochalcones reported in the literature. We aim to list the developments and pharmacological significance of aminochalcones by presenting a comprehensive list of the compounds with their significant biological activities. To understand the structure-activity relationship of aminochalcones, we will be categorizing these by the substitution position of the amino-group on both rings. Other categories will include N-alkyl, Nalkenyl, N-acyl, and N-sulfonyl aminochalcones. Thus the article will provide the versatile biological activities of aminochalcones and their relationship with the structure.

4-Aminochalcone and Derivatives
The most studied aminochalcone 1 contains a -NH2 substitution at position 4 on ring A ( Figure  3). The amino group on ring A increases the magnitude of the positive charge on the olefinic carbon atom adjacent to ring B. This has been proposed to enhance the electrophilic attack of these compounds on cancerous cells [36]. The purpose of this review article is to summarize and list the aminochalcones reported in the literature. We aim to list the developments and pharmacological significance of aminochalcones by presenting a comprehensive list of the compounds with their significant biological activities. To understand the structure-activity relationship of aminochalcones, we will be categorizing these by the substitution position of the amino-group on both rings. Other categories will include N-alkyl, N-alkenyl, N-acyl, and N-sulfonyl aminochalcones. Thus the article will provide the versatile biological activities of aminochalcones and their relationship with the structure.

4-Aminochalcone and Derivatives
The most studied aminochalcone 1 contains a -NH 2 substitution at position 4 on ring A (Figure 3). The amino group on ring A increases the magnitude of the positive charge on the olefinic carbon atom adjacent to ring B. This has been proposed to enhance the electrophilic attack of these compounds on cancerous cells [36].
Compound 1 has been extensively studied for its anticancer activity on multiple cell lines along with antibacterial and antifungal activities. Dimmock et al. [36] synthesized and evaluated the cytotoxic activities of several 4-aminochalcones, including 1 against the human Molt 4/C8, CEM T-lymphocytes, murine P388, and L1210 cancer cell lines. Compound 1 has also been prepared and tested by Romagnoli et al. [37] on five different cancer cell lines. Moreover, other groups have also tested 1 on several other cancer cell lines. The IC 50   Compound 1 has been extensively studied for its anticancer activity on multiple cell lines along with antibacterial and antifungal activities. Dimmock et al. [36] synthesized and evaluated the cytotoxic activities of several 4-aminochalcones, including 1 against the human Molt 4/C8, CEM Tlymphocytes, murine P388, and L1210 cancer cell lines. Compound 1 has also been prepared and tested by Romagnoli et al. [37] on five different cancer cell lines. Moreover, other groups have also tested 1 on several other cancer cell lines. The IC50 values are summarized in Table 1. 3.85 ± 0.28 µ g/mL (17.2 ± 1.3 µ M) * [42] * Values (in µ M) were calculated by us for uniformity using the µ g/mL values provided in the respective papers.  Compound 1 causes complete growth inhibition in the case of S. aureus DSM799 and A. niger DSM1957 microbial strains and showed significant prevention of growth for the other strains [42]. The results of these investigations [40,42] show 1 as a promising antibacterial agent.
Apart from cytotoxic and antimicrobial activities, compound 1 has also been tested for its inhibitory activity against the chlorinating activity of the myeloperoxidase (MPO) enzyme [44]. MPO has been explored as a target for anti-inflammatory therapy due to its ability to generate hypochlorous acid. Compound 1 was identified as a potent inhibitor of the chlorinating activity of MPO with an IC 50 value of 0.26 ± 0.04 µmol/L in a cell-free, purified MPO system. Interestingly, for a simple chalcone and aniline, both did not show any inhibition to the chlorinating activity of MPO, thus showing that the presence of both the amino and chalcone groups is important for any significant activity. The activity of 1 has also been compared with 4-hydroxychalcone, which also did not show any inhibitory activity. Thus, the presence of an amino group seems important compared to an electron-donating group. Moreover, the IC 50 value for 1 is comparable to 5-fluorotryptamine, which is considered a potent MPO inhibitor.
Several derivates of 4-aminochalcone have been synthesized by various groups over the years, with one of them being derivates with aliphatic alkylation on position 4 of ring B (Figures 4 and 5).
Compound 2 was tested for its cytotoxic activities by Dimmock et al. [36], Santos et al. [43], and Santos et al. [39], shown in Table 3.  Compound 2 was tested for its cytotoxic activities by Dimmock et al. [36], Santos et al. [43], and Santos et al. [39], shown in Table 3. 10.04 ± 1.6 µ M [36] Aminochalcone 2 has IC50 values similar to 1; thus, the anticancer activity of 4-aminochalcone does not increase or significantly decrease with the addition of a methyl group on ring B. Santos et al. [43] also reported the activity against canine malignant histiocytic cell line DH82 for 2, which was 74.7 ± 1.7%. This value is higher than 1, showing that the addition of a methyl group on ring B increased the potency of the compound.
In addition to the cytotoxic activity, the antioxidant activity of 2 has also been tested by Prasad et al. [45]. Many degenerative diseases such as atherosclerosis, cancer, inflammatory joint disease, asthma, diabetes, senile dementia, and degenerative eye disease originate from deleterious free radical reactions. Most free radical damage is caused by reactive oxidant species (ROS) which can  Aminochalcone 2 has IC 50 values similar to 1; thus, the anticancer activity of 4-aminochalcone does not increase or significantly decrease with the addition of a methyl group on ring B. Santos et al. [43] also reported the activity against canine malignant histiocytic cell line DH82 for 2, which was 74.7 ± 1.7%. This value is higher than 1, showing that the addition of a methyl group on ring B increased the potency of the compound.
In addition to the cytotoxic activity, the antioxidant activity of 2 has also been tested by Prasad et al. [45]. Many degenerative diseases such as atherosclerosis, cancer, inflammatory joint 7.5 ± 0.1 5.7 ± 0.5 6.0 ± 4.2 7.9 ± 0.7 12 ± 1 ---3h 8.6 ± 0.2 9.3 ± 0.2 25 ± 17 7.8 ± 0.1 35 ± 3 ---3i 5.6 ± 1.2 2.3 ± 0.3 7.8 ± 0.1 6.9 ± 0.8 8.8 ± 0 ---3j 10 ± 1 9.7 ± 0.6 25 ± 16 8.2 ± 0.9 29 ± 3 ---1 7.9 ± 0.8 8.5 ± 1.5 14 ± 3 7.7 ± 0.6 34 ± 1 5.28 9.63 ± 2.32 5.87 ± 0.15 Compounds 1 and 3a differ by a methoxy group on ring B. Though the cytotoxic activity between the two does not greatly differ in some cell lines, in others such as CEM and L1210, the IC 50 value for 1 is lower than that of 3a. Between the mono methoxylated compounds 3a-c, the values for 3c are higher than the other two for the Molt 4/C8, CEM, L1210, HeLa, FM3A, and HL-60 cell lines. The cytotoxic activity seems to decrease when the methoxy group is placed on position three on ring B. The most active compound for Molt 4/C8, CEM, L1210, HeLa, and FM3A is 3i, which is a tri-methoxylated aminochalcone. For the K562 cell line, compound 3d was the most potent compound, with activity comparable to imatinib and greater than Accutane. Imatinib and Accutane are commercial drugs used to treat different types of cancers. Compounds 3b and 3f showed activity higher than both imatinib and Accutane. Suwito et al. [40] showed that the methoxy-4-aminochalcones show better anticancer activity compared with methoxy chalcones and methoxy chalcones with 4-bromo; thus, the presence of 4-amino on ring A is essential for significant antiproliferative activity. The number and position of the methoxy group play a part in the anticancer activity of the compounds. Among known structures that bind to tubulin effectively are combretastatin A-4-5 and colchicine, which seem to have some structural overlap with some of these methoxy-substituted chalcones [41].
Apart from these cancer cell lines, the cytotoxic activity of 3a was also tested against a canine malignant histiocytic cell line (DH82) by Santos et al. [43], with the mean percentage of DH82 cell death equal to 46.6 ± 1.0%, which is quite less when compared with 1 (59.2 ± 4.2%) and 2 (74.7 ± 1.7%), thus showing that the substitution of a strong electron-donating group on ring B decreased cytotoxicity. A similar conclusion was made by Santos et al. [39] when they tested 3a against estrogen-receptor-positive breast cancer cells MCF-7 and the triple-negative breast cancer (TNBC) cells MDA-MB-23. Compound 3a did not show any significant activity against the two cell lines.
The antioxidant activities of 3a, 3h, and 3i were tested by Prasad et al. [45]. Compound 3i had an IC 50 value of 78.32 ± 1.59 µg/mL against the superoxide radical which was the best among all of the tested chalcones. Compounds 3a and 3h had IC 50 values of 80.09 ± 1.21 and 80.65 ± 1.58 µg/mL, respectively, against the superoxide radical. Compounds 3a, 3h, and 3i all showed a dose-dependent inhibition activity against the hydroxyl radical, with IC 50 values of 179.01 ± 1.58, 168.63 ± 1.55, and 158.18 ± 1.63 µg/mL, respectively. Against the ABTS radical cation, all three 3a, 3h, and 3i showed remarkable activities which were comparable to the standard drug, ascorbic acid. The IC 50 values were 56.91 ± 0.68, 52.89 ± 1.31, and 50.06 ± 1.41 µg/mL, respectively, amongst which 3i showed maximum activity from the tested compounds. For the inhibition of lipid peroxide, 3i showed the most potency as well (IC 50 value = 547.18 ± 2.01 µg/mL). The results of this study show that chalcones with electron-releasing groups such as methoxy have greater activity against oxidative species. Between 3a, 3h, and 3i, the scavenging activity increased as the number of methoxy substituents increased on ring B.
Apart from the cytotoxic activities of methoxy-substituted 4-aminochalcomes, the antimicrobial activity of 3a-f has also been tested by Suwito et al. [40] against Escherichia coli ATCC 25923, Staphylococcus aureus ATCC 259, and Candida albicans ATCC 10231 using different concentrations of the compounds, similar to 1. All of the compounds showed promising antibacterial activity, especially 3d, which showed the strongest inhibition activity against Escherichia coli ATCC 25923 (diameter of inhibition = 10.68 ± 0.16 mm at 500 µg/mL), Staphylococcus aureus ATCC 259 (diameter of inhibition = 10.33 ± 0.01 mm at 500 µg/mL), and Candida albicans ATCC 10231 (diameter of inhibition = 11.30 ± 0.15 mm at 500 µg/mL). The activity of compound 3d was comparable to the positive controls sulfamerazine and sulfadiazine.
4-Aminochalcones with hydroxy groups on ring B ( Figure 6) have also been synthesized and tested for their biological activities.
Molecules 2020, 25, 5381 9 of 120 receptor-positive breast cancer cells MCF-7 and the triple-negative breast cancer (TNBC) cells MDA-MB-23. Compound 3a did not show any significant activity against the two cell lines. The antioxidant activities of 3a, 3h, and 3i were tested by Prasad et al. [45]. Compound 3i had an IC50 value of 78.32 ± 1.59 µ g/mL against the superoxide radical which was the best among all of the tested chalcones. Compounds 3a and 3h had IC50 values of 80.09 ± 1.21 and 80.65 ± 1.58 µ g/mL, respectively, against the superoxide radical. Compounds 3a, 3h, and 3i all showed a dose-dependent inhibition activity against the hydroxyl radical, with IC50 values of 179.01 ± 1.58, 168.63 ± 1.55, and 158.18 ± 1.63 µ g/mL, respectively. Against the ABTS radical cation, all three 3a, 3h, and 3i showed remarkable activities which were comparable to the standard drug, ascorbic acid. The IC50 values were 56.91 ± 0.68, 52.89 ± 1.31, and 50.06 ± 1.41 µ g/mL, respectively, amongst which 3i showed maximum activity from the tested compounds. For the inhibition of lipid peroxide, 3i showed the most potency as well (IC50 value = 547.18 ± 2.01 µ g/mL). The results of this study show that chalcones with electron-releasing groups such as methoxy have greater activity against oxidative species. Between 3a, 3h, and 3i, the scavenging activity increased as the number of methoxy substituents increased on ring B.
Apart from the cytotoxic activities of methoxy-substituted 4-aminochalcomes, the antimicrobial activity of 3a-f has also been tested by Suwito et al. [40] against Escherichia coli ATCC 25923, Staphylococcus aureus ATCC 259, and Candida albicans ATCC 10231 using different concentrations of the compounds, similar to 1. All of the compounds showed promising antibacterial activity, especially 3d, which showed the strongest inhibition activity against Escherichia coli ATCC 25923 (diameter of inhibition = 10.68 ± 0.16 mm at 500 µ g/mL), Staphylococcus aureus ATCC 259 (diameter of inhibition = 10.33 ± 0.01 mm at 500 µ g/mL), and Candida albicans ATCC 10231 (diameter of inhibition = 11.30 ± 0.15 mm at 500 µ g/mL). The activity of compound 3d was comparable to the positive controls sulfamerazine and sulfadiazine.
4-Aminochalcones with hydroxy groups on ring B ( Figure 6) have also been synthesized and tested for their biological activities. 4a 4b Figure 6. Chemical structures of 4-aminochalcone derivatives with hydroxy substitutions on ring B.
Both 4a and 4b were tested as α-glucosidase inhibitors, along with several sulfonamide chalcones [47]. α-Glucosidase inhibitors can be used in the treatment of cancer, diabetes, and viral diseases. As glycosidase enzymes are responsible for the processing and synthesis of complex carbohydrates, inhibitors of these molecules can be important tools in glycobiology and can help modulate cellular functions along with biological recognition processes. α-Glucosidases catalyze the release of α-D-glucopyranose from the non-reducing ends of various substrates, inhibitors of which can control the uptake of dietary carbohydrates and, thus, can decrease postprandial hyperglycemia, which may be useful in treating diabetes or obesity. Compounds 4a and 4b showed strong inhibitory activities against the three glycosidases that it was tested on. The IC50 values for 4a were 41.0 and 268.9 µ M respectively against α-glucosidase from baker's yeast and α-amylase from Bacillus licheniformis. The values for 4b were 62.1 and 126.8 µ M against α-glucosidase from the baker's yeast and ß-amylase from barley. While this activity did not exceed that of the sulfonamides, it was still considered significant, especially when compared with the respective 3-aminochalcones.
Kang et al. [48] tested the inhibitory activities of 4a and 4b against ß-secretase (BACE1), which is strongly associated with the onset of Alzheimer's disease (AD) and had IC50 values of 48.2 ± 1.2 and 17.7 ± 0.8 µM, respectively. The 3,4-dihydroxy derivate was more potent than the one bearing a 4- Both 4a and 4b were tested as α-glucosidase inhibitors, along with several sulfonamide chalcones [47]. α-Glucosidase inhibitors can be used in the treatment of cancer, diabetes, and viral diseases. As glycosidase enzymes are responsible for the processing and synthesis of complex carbohydrates, inhibitors of these molecules can be important tools in glycobiology and can help modulate cellular functions along with biological recognition processes. α-Glucosidases catalyze the release of α-D-glucopyranose from the non-reducing ends of various substrates, inhibitors of which can control the uptake of dietary carbohydrates and, thus, can decrease postprandial hyperglycemia, which may be useful in treating diabetes or obesity. Compounds 4a and 4b showed strong inhibitory activities against the three glycosidases that it was tested on. The IC 50 values for 4a were 41.0 and 268.9 µM respectively against α-glucosidase from baker's yeast and α-amylase from Bacillus licheniformis. The values for 4b were 62.1 and 126.8 µM against α-glucosidase from the baker's yeast and ß-amylase from barley. While this activity did not exceed that of the sulfonamides, it was still considered significant, especially when compared with the respective 3-aminochalcones. Kang et al. [48] tested the inhibitory activities of 4a and 4b against ß-secretase (BACE1), which is strongly associated with the onset of Alzheimer's disease (AD) and had IC 50 values of 48.2 ± 1.2 and 17.7 ± 0.8 µM, respectively. The 3,4-dihydroxy derivate was more potent than the one bearing a 4-hydroxy substituent. While they exhibited inhibitory activity, the respective sulfonamide chalcones were manyfold more potent than these two compounds (and will be discussed in their section).
Similar to compounds 1 and 2, 4a was tested for its inhibitory activity against the chlorinating activity of the myeloperoxidase (MPO) [44]. While both 1 and 2 showed potency towards MPO, the IC 50 value for 4a was reported to be greater than 50.00 µM. This indicated that the presence of an easily oxidizable group cancels the inhibitory activity of the aminochalcone.
Seo et al. [49] also reported the anti-pigmentary effect of 4a. It had an IC 50 value of 4.8 µM for tyrosinase enzyme and 48.7 µM against the melanin formation cell. The compound was more potent than kojic acid (IC 50 = 16.3 µM), a known inhibitor of tyrosinase.
Several 4-aminochalcones with halogen substitutions, particularly chloro-, fluoro-, and bromo-on ring B have also been reported by various research groups over the years. The 4-aminochalcones with various chlorine substitutions have been reported by four research groups and are shown in Figure 7. The anticancer activity reported for 5a-e by various research groups is shown in Table 5.  The cytotoxicity for Molt 4/C8, CEM, P388, and L1210 was retained when chlorine substitutions were introduced on ring B when compared with 1. The IC50 values for both 5a and 5e were found comparable to those of melphalan against some cell lines (IC50 values of melphalan: 3.24 ± 0.79, 2.47 ± 0.30, 0.22 ± 0.01, and 2.13 ± 0.03 µ M against Molt 4/C8, CEM, P388, and L1210, respectively). Both 5a and 5e were more potent to the cell lines as compared to the acylated versions of these  The cytotoxicity for Molt 4/C8, CEM, P388, and L1210 was retained when chlorine substitutions were introduced on ring B when compared with 1. The IC 50 values for both 5a and 5e were found comparable to those of melphalan against some cell lines (IC 50 values of melphalan: 3.24 ± 0.79, 2.47 ± 0.30, 0.22 ± 0.01, and 2.13 ± 0.03 µM against Molt 4/C8, CEM, P388, and L1210, respectively). Both 5a and 5e were more potent to the cell lines as compared to the acylated versions of these aminochalcones [36]. Mai et al. [38] also determined the antiproliferative activities of 5a and 5d, and the study revealed that 5a was more potent than 5d against most of the cancer cell lines, with its best activity against the CEM-SS cell line. The activities of 5d were poor against all the cell lines investigated in this study [38]. The 3-chlorophenyl derivative, 5c, was the most potent compound against the MCF-7 cell line amongst the tested chloro-4-aminochalcones; on the other hand, 5a showed better activity against the MDA-MB-231 cells. These compounds were more potent than other derivatives with cyano, nitro, and bromo groups [39]. Compound 5a was the more potent compound amongst all tested by Santos et al. against the canine malignant histiocytic cell line DH82 [43]. The mean percentage cell death of DH82 was 91.0 ± 1.3 at 15.0 µg/mL of the compound. Compound 5a was subsequently selected for cytotoxic assay against DH82 and MDCK (non-tumorigenic Madin-Darby canine kidney) cells. The IC 50 values were 31.4 and 57.2 µM, respectively. The selectivity ratio was 1.8. The activity of 5a against DH82 was greater than etoposide (IC 50 = 95.5 µM), the reference drug used.
Compounds 5a, 5b, and 5d were also tested for their antioxidant activity by Prasad et al. [45] (Table 6). Amongst the three chloro-4-aminochalcones, 5a, the 4-chloro-4-aminochalcone was found to be the more potent and showed dose-dependent inhibition against the superoxide radical, the hydroxyl radical, and lipid peroxidation. The activity of 5a was comparable to the reference ascorbic acid (IC 50 = 45.42 ± 1.24 µg/mL) for the ABTS cation radical. Continuing with halogens, research groups also reported the synthesis and activity of fluoro-4-aminochalcones ( Figure 8). The anticancer activity of the three mono fluoro derivatives was reported by Santos et al. [39] against estrogen-receptor-positive breast cancer cells MCF-7 and the triple-negative breast cancer (TNBC) cells MDA-MB-231. Compound 6a did not show any significant activity, and the IC50 values were not determined. The IC50 values for 6b were >100 and 74.1 ± 1.2 µ M for MCF-7 and MDA-MB-231 cancer cells, respectively. Compound 6c was the more potent against these cells among all of the compounds tested with IC50 values 13.2 ± 3.5 and 34.7 ± 5.2 µ M, respectively. Compound 6c induced apoptosis rather than necrosis in both cells. The 3-chloro-4-aminochalcone compound 5c was also very active against the MCF-7 cell line. A comparison among values for the different compounds tested showed that more electronegative halogens on ring B showed a higher degree of antiproliferative activity against the MCF-7 and MDA-MB-231 cancer cell lines. Electron-donating groups, on the other hand, had a negative effect on bioactivity, as can be seen from the values of compounds 2 and 3a.
The cytotoxic activity for 6a was also tested against the canine malignant histiocytic cell line DH82 and non-tumorigenic Madin-Darby canine kidney MDCK cells [43] (IC50 = 34.4 and 70.1 µM, respectively). The selectivity ratio was 2.0. Thus, 6a had a greater selectivity against the DH82 cancer The anticancer activity of the three mono fluoro derivatives was reported by Santos et al. [39] against estrogen-receptor-positive breast cancer cells MCF-7 and the triple-negative breast cancer (TNBC) cells MDA-MB-231. Compound 6a did not show any significant activity, and the IC 50 values were not determined. The IC 50 values for 6b were >100 and 74.1 ± 1.2 µM for MCF-7 and MDA-MB-231 cancer cells, respectively. Compound 6c was the more potent against these cells among all of the compounds tested with IC 50 values 13.2 ± 3.5 and 34.7 ± 5.2 µM, respectively. Compound 6c induced apoptosis rather than necrosis in both cells. The 3-chloro-4-aminochalcone compound 5c was also very active against the MCF-7 cell line. A comparison among values for the different compounds tested showed that more electronegative halogens on ring B showed a higher degree of antiproliferative activity against the MCF-7 and MDA-MB-231 cancer cell lines. Electron-donating groups, on the other hand, had a negative effect on bioactivity, as can be seen from the values of compounds 2 and 3a.
The cytotoxic activity for 6a was also tested against the canine malignant histiocytic cell line DH82 and non-tumorigenic Madin-Darby canine kidney MDCK cells [43] (IC 50 = 34.4 and 70.1 µM, respectively). The selectivity ratio was 2.0. Thus, 6a had a greater selectivity against the DH82 cancer cell line. The three most active compounds in this paper were 2, 5a, and 6a. Compound 2, having a methyl group, is electron-donating, and the halogen-substituted compounds are electron-withdrawing atoms. Thus, it was concluded that the electronic effect of the substituent did not matter much for the antiproliferative activity against these particular cell lines. The halogen chalcones 5a and 6a along with the methyl chalcone 2 are lipophilic and more active than the other compounds tested. Thus, compounds with hydrophobic substitutions on ring B were more potent.
Apart from the anticancer activity, the antioxidant activity for 6a was also tested by Prasad et al. [45] with IC 50 values of 79.73 ± 1.58, 175.71 ± 1.61, 61.06 ± 1.78, and 552.18 ± 2.98 µg/mL against the superoxide radical, hydroxyl radical, ABTS cation radical, and lipid peroxidation, respectively. While it was not the most potent compound among all those tested, 6a showed dose-dependent activity against all of the radicals tested. Its activity was comparable to the standard ascorbic acid for the ABTS cation and superoxide radical. Compound 6a was also tested for its inhibitory activity against the chlorinating activity of the myeloperoxidase (MPO) enzyme by Zeraik et al. [44] and had an IC 50 value of 0.25 ± 0.08 µmol/L in a cell-free, purified MPO system. This value is similar to those of 1 and 2. Similar values for compounds substituted with methyl and fluorine on ring B showed that the main property contributing to MPO inhibition is the presence of both amino and chalcone groups in the compound.
4-Aminochalcone compounds with bromine substitutions on ring B ( Figure 9) have also been reported. Both 7a and 7b were also tested against the estrogen-receptor-positive breast cancer cells MCF-7 and the triple-negative breast cancer (TNBC) cells MDA-MB-231 [39]. However, these derivatives were not very potent towards the cell lines, especially when compared with compounds substituted with fluorine and chlorine.
The antioxidant activity [45] for 7b was tested, and the IC50 values were reported to be 85.65 ± 1.30, 204.33 ± 1.53, 74.45 ± 0.96, and 600.85 ± 2.38 µ g/mL against the superoxide radical, hydroxyl radical, ABTS cation radical, and lipid peroxidation, respectively. While this activity was not terrible, it was not comparable to that of ascorbic acid or other derivatives of 4-aminochalcones.
The 4-nitro-4-aminochalcone compound ( Figure 10) has also been reported in many articles of some groups. Both 7a and 7b were also tested against the estrogen-receptor-positive breast cancer cells MCF-7 and the triple-negative breast cancer (TNBC) cells MDA-MB-231 [39]. However, these derivatives were not very potent towards the cell lines, especially when compared with compounds substituted with fluorine and chlorine.
The antioxidant activity [45] for 7b was tested, and the IC 50 values were reported to be 85.65 ± 1.30, 204.33 ± 1.53, 74.45 ± 0.96, and 600.85 ± 2.38 µg/mL against the superoxide radical, hydroxyl radical, ABTS cation radical, and lipid peroxidation, respectively. While this activity was not terrible, it was not comparable to that of ascorbic acid or other derivatives of 4-aminochalcones.
The 4-nitro-4-aminochalcone compound ( Figure 10) has also been reported in many articles of some groups. The cytotoxic activity for 8 was tested against many different cancer cell lines (Table 7).  The cytotoxic activity for 8 was tested against many different cancer cell lines (Table 7). The IC 50 values [36] for the Molt 4/C8, CEM, P388, and L1210 cell lines against compound 8 were better when compared with the simple 4-aminochalcone 1. The activity for 8 was better than all derivatives, including chloro and methyl, tested for the Molt 4/C8, P388, and L1210 cells. The cell lines tested by Kozlowska et al. [42] showed 8 to be decently potent. Among these cell lines, compound 8 exhibited the highest cytotoxic activity against the HT-29 cell line. Compound 8 exhibited activity better than cisplatin against the HT-29, LoVo, and LoVo/DX cell lines (IC 50 values of cisplatin: 16.73 ± 0.58, 1.49 ± 0.13, 2.09 ± 0.12, and 2.03 ± 0.17 µg/mL against HT-29, LS180, LoVo, and LoVo/DX, respectively). However, it was also toxic to the normal green monkey fibroblast line COS7 (IC 50 = 3.10 ± 0.50 µg/mL) used to determine the toxicity of the compounds. Compound 8 was also tested for its anticancer activity against MCF-7 and MDA-MB-231 [39]; however, no significant activity was observed. The mean percentage of DH82 cell death [43] was 52.4 ± 6.7% for 8.
Kozlowska et al. [42] tested the antimicrobial activity of 8 against two strains of bacteria, E. coli ATCC10536 and S. aureus DSM799; one strain of yeast, C. albicans DSM1386; and three strains of fungi, A. alternata CBS1526, F. linii KB-F1, and A. niger DSM1957. Compound 8 prevented the growth of E. coli with minimum inhibitory concentration (MIC) value equal to 0.25 mg/mL, two times stronger than reference oxytetracycline (MIC = 0.5 mg/mL). Compound 8 also prevented the growth of S. aureus and F. linii (MIC = 0.25 and 1.0 mg/mL).
The potency of 9 against oxidative species, on the other hand, was quite good. The IC50 values [45] against the superoxide radical, hydroxyl radical, ABTS cation radical, and lipid peroxidation were 78.87 ± 1.32, 151.48 ± 1.09, 50.36 ± 1.22, and 423.08 ± 2.26 µ g/mL, respectively. Compound 9 was one of the most potent compounds tested in this analysis and showed dose-dependent inhibition activities against all assays. It showed the maximum activity, comparable to the standard ascorbic acid against the hydroxyl radical, ABTS radical cation, and inhibition of lipid peroxidation. Romagnoli et al. [37] tested 9 against the L1210, FM3A, Molt4, CEM, and HeLa cell lines with IC 50 values equaling 67 ± 33, 96 ± 32, 9.9 ± 1.0, 20 ± 3, and 28 ± 10 µM. Compound 9 was concluded to show weak antiproliferative activity towards these cell lines.
The potency of 9 against oxidative species, on the other hand, was quite good. The IC 50 values [45] against the superoxide radical, hydroxyl radical, ABTS cation radical, and lipid peroxidation were 78.87 ± 1.32, 151.48 ± 1.09, 50.36 ± 1.22, and 423.08 ± 2.26 µg/mL, respectively. Compound 9 was one of the most potent compounds tested in this analysis and showed dose-dependent inhibition activities against all assays. It showed the maximum activity, comparable to the standard ascorbic acid against the hydroxyl radical, ABTS radical cation, and inhibition of lipid peroxidation. Compound 8, having an electron-withdrawing group on ring B, was not very potent against these assays. It was, thus, concluded that electron-releasing substitutions like methoxy and dimethylamino on ring B contribute to the antioxidant activity.
The 4-aminochalcones synthesized by Santos et al. [39] included those shown in Figure 13.  Some derivatives containing pyridine rings have also been reported ( Figure 14). Compounds 17a and 17b were synthesized by Santos et al. [39] using the Claisen-Schmidt aldol condensation method, and their cytotoxic activity was tested against the MCF-7 and MDA-MB-231 cancer cell lines as well. Compound 17b showed significant antiproliferative activity against the MCF-7 cell line with an IC50 value of 15.7 ± 5.9 µ M. Compound 17b was also potent against the MDA-MB-231 cell line (IC50 = 33.9 ± 7.1 µ M). Apart from the 4-fluorophenyl derivative 6c, 17b was the only compound among those reported in the manuscript which showed significant potency against both cell lines. Compound 17b induced apoptosis rather than necrosis in both cells and upregulated the p53 expression in the MCF-7 cell line. Compound 17a was active against the MCF-7 and showed a percentage of metabolically viable cells (%MVC) value of 61.3 ± 3.4. Its IC50 value was not determined.
The antioxidant activity for 17a, 17b, and 17c was tested by Prasad et al. [45] Many 4aminochalcones reported in this manuscript have already been discussed earlier, with some of them showing significant antioxidant activity comparable to the reference ascorbic acid. Compounds 17a, 17b, and 17c, however, did not show very significant activity against the superoxide, hydroxyl, ABTS cation radicals, and lipid peroxidation ( Table 9). The IC50 values for these compounds were not comparable to ascorbic acid or the more potent compounds tested by the group. Table 9. IC50 values of chloro-4-aminochalcones 17a, 17b, and 17c, expressed in µ g/mL. Prasad et al. [45] have also reported the 2-quinolinyl 4-aminochalcone derivative ( Figure 15) and aminochalcone containing anthracene ring ( Figure 16). Compounds 17a and 17b were synthesized by Santos et al. [39] using the Claisen-Schmidt aldol condensation method, and their cytotoxic activity was tested against the MCF-7 and MDA-MB-231 cancer cell lines as well. Compound 17b showed significant antiproliferative activity against the MCF-7 cell line with an IC 50 value of 15.7 ± 5.9 µM. Compound 17b was also potent against the MDA-MB-231 cell line (IC 50 = 33.9 ± 7.1 µM). Apart from the 4-fluorophenyl derivative 6c, 17b was the only compound among those reported in the manuscript which showed significant potency against both cell lines. Compound 17b induced apoptosis rather than necrosis in both cells and upregulated the p53 expression in the MCF-7 cell line. Compound 17a was active against the MCF-7 and showed a percentage of metabolically viable cells (%MVC) value of 61.3 ± 3.4. Its IC 50 value was not determined.

Compound
The antioxidant activity for 17a, 17b, and 17c was tested by Prasad et al. [45] Many 4-aminochalcones reported in this manuscript have already been discussed earlier, with some of them showing significant antioxidant activity comparable to the reference ascorbic acid. Compounds 17a, 17b, and 17c, however, did not show very significant activity against the superoxide, hydroxyl, ABTS cation radicals, and lipid peroxidation ( Table 9). The IC 50 values for these compounds were not comparable to ascorbic acid or the more potent compounds tested by the group. Prasad et al. [45] have also reported the 2-quinolinyl 4-aminochalcone derivative ( Figure 15) and aminochalcone containing anthracene ring ( Figure 16).    66, and 652.25 ± 1.44 µ g/mL against the superoxide radical, hydroxyl radical, ABTS cation radical, and lipid peroxidation, respectively. Lack of significant activity might be due to the absence of any strong electron-releasing group such as methoxy or dimethylamino on ring B, as derivatives containing these substitutions were more potent.
4-amino-1-naphthylchalcone 20 and its methylated derivative 21 ( Figure 17) were synthesized by Seba et al. [50], and their activity against osteosarcoma cells was reported.   44 µg/mL against the superoxide radical, hydroxyl radical, ABTS cation radical, and lipid peroxidation, respectively. Lack of significant activity might be due to the absence of any strong electron-releasing group such as methoxy or dimethylamino on ring B, as derivatives containing these substitutions were more potent.
4-amino-1-naphthylchalcone 20 and its methylated derivative 21 ( Figure 17) were synthesized by Seba et al. [50], and their activity against osteosarcoma cells was reported. Osteosarcoma is the most recurrent malignant bone tumor. This tumor shows a high propensity for local invasion and distant metastasis. Due to this, the long-term survival rate of osteosarcoma patients with metastasis is decreased by 20-30% [51]. Seba et al. [50] studied the inhibitory effects of 20 and 21 against osteosarcoma migration. They found that, while these compounds neither induce apoptosis in osteosarcoma cells can suppress tumor cell lines U2OS and SOAS, they showed inhibitory effect against migration and invasion of osteosarcoma cells. This effect was more potent in p53-expressing cells, namely, U2OS. They increased p53 expression and reduced the activity and expression of two matrix metalloproteinases: MMP-2 and MMP-9. These compounds also downregulated the epithelial-mesenchymal transition (EMT). The migration and invasion of tumor cells towards the vascular/lymphatic system involves MMPs, which ultimately triggers metastasis. Tumor cells undergo various changes during their EMT, which relate to amplified migration, invasion, and metastasis of these cells. Thus, the targets of compounds 20 and 21 are important in the process of migration and invasion of osteosarcoma cells.
Santos et al. [43] reported the cytotoxic activity of 20 against the canine malignant histiocytic cell line DH82 as the mean percentage of DH82 cell death, which was 40.3 ± 0.6.
A 2-napthyl derivative of 4-aminochalcone, 22, was also synthesized and tested by Santos et al. [43] (Figure 18). It showed a mean percentage of DH82 cell death as 40.4 ± 3.7. Osteosarcoma is the most recurrent malignant bone tumor. This tumor shows a high propensity for local invasion and distant metastasis. Due to this, the long-term survival rate of osteosarcoma patients with metastasis is decreased by 20-30% [51]. Seba et al. [50] studied the inhibitory effects of 20 and 21 against osteosarcoma migration. They found that, while these compounds neither induce apoptosis in osteosarcoma cells can suppress tumor cell lines U2OS and SOAS, they showed inhibitory effect against migration and invasion of osteosarcoma cells. This effect was more potent in p53-expressing cells, namely, U2OS. They increased p53 expression and reduced the activity and expression of two matrix metalloproteinases: MMP-2 and MMP-9. These compounds also downregulated the epithelial-mesenchymal transition (EMT). The migration and invasion of tumor cells towards the vascular/lymphatic system involves MMPs, which ultimately triggers metastasis. Tumor cells undergo various changes during their EMT, which relate to amplified migration, invasion, and metastasis of these cells. Thus, the targets of compounds 20 and 21 are important in the process of migration and invasion of osteosarcoma cells.
Santos et al. [43] reported the cytotoxic activity of 20 against the canine malignant histiocytic cell line DH82 as the mean percentage of DH82 cell death, which was 40.3 ± 0.6.
A 2-napthyl derivative of 4-aminochalcone, 22, was also synthesized and tested by Santos et al. [43] (Figure 18). It showed a mean percentage of DH82 cell death as 40.4 ± 3.7. Both chalcones with naphthyl rings showed poor activity against the DH82 cell line. 4-aminochalcones with heterocycles instead of the phenyl ring B have also been synthesized ( Figure 19). Both chalcones with naphthyl rings showed poor activity against the DH82 cell line. 4-aminochalcones with heterocycles instead of the phenyl ring B have also been synthesized ( Figure 19). The antiproliferative activity of compounds 23 and 24 was reported by Santos et al. [43] against the canine malignant histiocytic cell line DH82. The mean percentages of DH82 cell death values were 18.8 ± 4.0 and 43.6 ± 3.7, respectively. Thus, neither compound showed significant activity against the cell line and 23 had the poorest activity amongst all of the compounds reported in the manuscript. In addition to this, 23 was also tested by Santos et al. [39] against the estrogen-receptor-positive breast cancer cells MCF-7 and the triple-negative breast cancer (TNBC) cells MDA-MB-231. It showed %MVC values of 104.5 ± 3.6 and 100.1 ± 7.1 against the cell lines, respectively. Thus, it can be concluded that these compounds do not show significant cytotoxic activity.
Moving towards the end of our discussion for 4-aminochalcones, compound 25 ( Figure 20) was synthesized by Nielsen et al. [52] and tested for its antibiotic activity along with many other chalcones. The antiproliferative activity of compounds 23 and 24 was reported by Santos et al. [43] against the canine malignant histiocytic cell line DH82. The mean percentages of DH82 cell death values were 18.8 ± 4.0 and 43.6 ± 3.7, respectively. Thus, neither compound showed significant activity against the cell line and 23 had the poorest activity amongst all of the compounds reported in the manuscript. In addition to this, 23 was also tested by Santos et al. [39] against the estrogen-receptor-positive breast cancer cells MCF-7 and the triple-negative breast cancer (TNBC) cells MDA-MB-231. It showed %MVC values of 104.5 ± 3.6 and 100.1 ± 7.1 against the cell lines, respectively. Thus, it can be concluded that these compounds do not show significant cytotoxic activity.
Moving towards the end of our discussion for 4-aminochalcones, compound 25 ( Figure 20) was synthesized by Nielsen et al. [52] and tested for its antibiotic activity along with many other chalcones.  Compound 25 was tested against the S. aureus ATCC33591 (resistant to methicillin), E. faecium 17501 (vancomycin-resistant clinical isolate), and E. faecium ATCC29212 bacterial cell lines and showed MIC values of 10, 10, and 20 µM, respectively. As the values indicate, 25 had no significant effect on the activity. However, it showed some influence on the bacterial membrane. This is likely due to the protonation of the dimethylamino group on ring B.

2-Aminochalcone and Derivatives
Aminochalcone 26 ( Figure 21) with a -NH2 substitution at position 2 on ring A is the simplest among 2-aminochalcones. Kozlowska et al. [42] obtained it through a modified protocol for a base-catalyzed Claisen-Schmidt condensation described by Amir et al. [53] using 2-aminoacetophenone and benzaldehyde. Following synthesis, its anticancer activity was tested against various cancer cell lines using green monkey fibroblast COS7, selected as the normal cell line to determine toxicity (Table 10)   Aminochalcone 26 was the strongest inhibitor of HT-29 cell line proliferation, as indicated by the values in Table 10. It exhibits activity almost 12 folds higher than that of reference compound cisplatin (IC50 = 16.73 ± 0.58 µ g/mL) and 4 folds lower than that of doxorubicin (IC50 = 0.33 ± 0.02 µ g/mL). Its cytotoxicity against the COS7 normal cell line indicated its poor selectivity against cancer cells [42]. Additionally, in comparison to the 4-aminochalcone discussed earlier, the IC50 values of 26 are lower for the cell lines in Table 1. This increase in potency is caused just by the change in position of the amine group from 4 to 2 on ring A. Following synthesis, its anticancer activity was tested against various cancer cell lines using green monkey fibroblast COS7, selected as the normal cell line to determine toxicity (Table 10)   Aminochalcone 26 was the strongest inhibitor of HT-29 cell line proliferation, as indicated by the values in Table 10. It exhibits activity almost 12 folds higher than that of reference compound cisplatin (IC 50 = 16.73 ± 0.58 µg/mL) and 4 folds lower than that of doxorubicin (IC 50 = 0.33 ± 0.02 µg/mL). Its cytotoxicity against the COS7 normal cell line indicated its poor selectivity against cancer cells [42].
Additionally, in comparison to the 4-aminochalcone discussed earlier, the IC 50 values of 26 are lower for the cell lines in Table 1. This increase in potency is caused just by the change in position of the amine group from 4 to 2 on ring A.
Mai et al. [38] reported that the selectivity ratio (IC 50 HEK-293/IC 50 HT-29) of 26 (ratio > 22.78) fulfilled the threshold limit (ratio ≥ 5); it was one of the promising anticancer agents. They also observed that, among all the chalcones tested, 26 showed the most potent antiproliferative effect against HT-29 cells, indicating that the -NH2 group on ring A plays an important role. The anti-proliferative effects exhibited by the aminochalcone 26 were due to apoptosis rather than necrosis and were dose-dependent.
Kozlowska et al. [42] investigated the antimicrobial activity of 26 against bacterial strain Staphylococcus aureus DSM799 and strains of fungi, Alternaria alternata CBS1526 and Aspergillus niger DSM1957. The minimum inhibitory concentration (MIC) values were evaluated and compared with reference substances, such as oxytetracycline (against bacteria) and nystatin (against fungi). The MIC value of 26 was 1.0 mg/mL for A. alternata. Complete growth inhibition was observed in cases of S. aureus (MIC = 0.25 mg/mL) and particularly A. niger (MIC = 0.125 mg/mL), which was two times more effective than nystatin.
Furthermore, the antimicrobial activity of 26 against several bacteria was tested and reported by Ruanwas et al. [54] Against all the gram-positive bacteria-Bacillus subtilis, Staphylococcus aureus, Enterococcus faecalis TISTR 459, methicillin-resistant Staphylococcus aureus (MRSA) ATCC 43300, and vancomycin-resistant Enterococcus faecalis (VRE) ATCC 51299-and gram-negative bacteria-Salmonella typhi, Shigella sonei, and Pseudomonas aeruginosa-compound 26 showed MIC values >300 µg/mL, which were significantly greater than the vancomycin standard (MIC < 2.34 µg/mL). These results are similar to the antimicrobial activity of 4-aminochalcone, which differs only by the position of the -NH2 group on ring A. This suggests that a change in position from 4 to 2 does not cause a big difference in antimicrobial activity. The same group also tested the antioxidant activity of compound 26 via a DPPH (2,2-diphenyl-1-picrylhydrazyl radical) antioxidant assay, which was later compared to the standard ascorbic acid. Aminochalcone 26 showed a percentage inhibition of 18.7%, which was the highest among the aminochalcones tested for free radical scavenging. However, it was notably less than the ascorbic acid standard, which exhibits 92.1% inhibition [54].
A variety of 2-aminochalcone derivatives with substitutions on ring B have been synthesized and reported for biological activity by Santos et al. [43].
Aminochalcone 27 ( Figure 22) is an analog of the methylated 4-aminochalcone discussed earlier. It was synthesized and evaluated for anticancer activity against the canine malignant histiocytic cell line (DH82). The mean percentage of cell death was found to be 88.9 ± 1.5 at 15.0 µg/mL of the compound. Compound 27 was one of the three most active compounds tested due to its selective toxicity and apoptosis induction in DH82 cells compared to a nontumorigenic canine cell line (Madin-Darby canine kidney cells, MDCK). Compound 27 also showed a slight increase in cytotoxicity in comparison to its 4-aminochalcone analog. The compound largely owes its activity to the presence of a hydrophobic group on ring B. Similarly, against DH82 and MDCK cells, a nontumorigenic cell line, the IC 50 values of 27 were 38.2 µM and 23.3 µM, reflecting approximately three times more potency against DH82 than the reference antitumor drug etoposide (IC 50 = 95.5 µM). It was also observed that 27 induces cell death through apoptosis rather than necrosis in canine cells. Therefore, it can be deduced that compound 27 possesses a remarkable potential for anticancer activity against the tested cell lines.  The anticancer activity of 28c, 29, and 31b against canine malignant histiocytic cell line (DH82) was determined as the mean percentage of DH82 cell death ± SEM at 15.0 mg/mL of the compound. The activities of 28c, 29, and 31b were 76.6 ± 0.1, 83.2 ± 5.7, and 87.0 ± 7.5, respectively. These halogenated 2-aminochalcones exhibited cytotoxic activity similar to that of their halogenated 4aminochalcone analogs [43].
Like 26, compound 29 was also prepared and tested against ten cancer cell lines for antiproliferative activity by Mai et al. [38]. The IC50 values of 29 are summarized in Table 11. From the values in Table 11, we can infer that the activity of 29 is the best against the HT-29 cell line. It is seen from the comparison of the activity of 29 with 26 that compound 26 is more potent The anticancer activity of 28c, 29, and 31b against canine malignant histiocytic cell line (DH82) was determined as the mean percentage of DH82 cell death ± SEM at 15.0 mg/mL of the compound. The activities of 28c, 29, and 31b were 76.6 ± 0.1, 83.2 ± 5.7, and 87.0 ± 7.5, respectively. These halogenated 2-aminochalcones exhibited cytotoxic activity similar to that of their halogenated 4-aminochalcone analogs [43].
Like 26, compound 29 was also prepared and tested against ten cancer cell lines for antiproliferative activity by Mai et al. [38]. The IC 50 values of 29 are summarized in Table 11. From the values in Table 11, we can infer that the activity of 29 is the best against the HT-29 cell line. It is seen from the comparison of the activity of 29 with 26 that compound 26 is more potent against most cell lines including A549, HEPG2, CNE-1, K562, and CEM-SS whereas 29 has a higher antiproliferative activity against the Caov-3 cell line and HT-29 shows similar values for both 26 and 29. Therefore, the presence of -NH2 on ring A position 2 has a more significant contribution to the anticancer activity as opposed to the substitutions on ring B.
More derivatives of 2-aminochalcones, some of which were novel with different substituents on ring B (Figure 24), were synthesized by Kozlowska et al. [42], Mai et al. [38], and Zhang at al. [55]. The biological activity of the compounds was investigated against cancer cell lines and different microbes. Table 12 shows the IC50 values of compounds 32b, 33, 35, and 36 against cancer cell lines as investigated by Kozlowska et al. [42] and Mai et al. [38]. Compound 33 showed IC50 values lower than 36 but higher than 32b for the cancer cell lines tested. Similar to the anticancer effect of compound 27 with the methyl group on ring B, the higher potency of 33 compared to 36 is also due to the hydrophobicity of the ethyl group. Also, the cytotoxicity of 33 against the COS7 normal cell line is lower than that of 26, the simple 2aminochalcone which indicates the positive effect of ethyl substituent on ring B. Besides, the The biological activity of the compounds was investigated against cancer cell lines and different microbes. Table 12 shows the IC 50 values of compounds 32b, 33, 35, and 36 against cancer cell lines as investigated by Kozlowska et al. [42] and Mai et al. [38]. Compound 33 showed IC 50 values lower than 36 but higher than 32b for the cancer cell lines tested. Similar to the anticancer effect of compound 27 with the methyl group on ring B, the higher potency of 33 compared to 36 is also due to the hydrophobicity of the ethyl group. Also, the cytotoxicity of 33 against the COS7 normal cell line is lower than that of 26, the simple 2-aminochalcone which indicates the positive effect of ethyl substituent on ring B. Besides, the anticancer activity of 36 is observed to be the weakest and it was not tested against some cancer cell lines. The activity of 32b is impressive in comparison to the others tested. This compound was made and investigated for bioactivity by both groups [38,42] as shown in Table 12 as IC 50 values. Kozlowska and colleagues [42] found compound 32b to be slightly more potent against the common cell line HT-29 but still less active than compound 26. When compared with 33 and 36, 32b was more potent against all four cancer cell lines while also exhibiting toxicity against the COS7 normal cell line. Compound 35 showed moderate anticancer activity, with lower toxicity against the COS7 normal cell line, but there was no notable feature observed in the overall activity of 35 [42]. Mai et al. [38] reported that, since 32b exhibited good anticancer activity against most of the cell lines tested and the selectivity ratio (IC 50 HEK-293/IC 50 HT-29) of 32b (ratio = 6.77) was greater than the threshold value (ratio ≥ 5), it was one of the promising anticancer agents like 26.
In addition to anticancer activity, Kozlowska et al. [42] also determined the antimicrobial activity in terms of minimum inhibitory concentrations (MIC) of compounds 33, 34, 36, and 32b against bacterial and fungal strains. Compound 32b was tested against Escherichia coli ATCC10536 with (MIC = 0.25 mg/mL), Candida albicans DSM1386, and F. linii KB-F1, with MIC values = 0.5 mg/mL each. These values are almost equivalent to the standard drugs against which they were compared, and 32b showed MIC values lower than its 4-aminochalcone analog, thus revealing its antimicrobial potential and the significant impact of the position of the NH2 group (ring A) on the biological activity of aminochalcones. Compound 33 showed MIC value = 0.5 mg/mL when tested against Escherichia coli ATCC10536, which was equal to the standard oxytetracycline. Compound 34 was only tested for antimicrobial activity and displayed MIC values of 0.25 mg/mL, 0.25 mg/mL, and 0.5 mg/mL against Escherichia coli ATCC10536, Staphylococcus aureus DSM799, and Candida albicans DSM1386, respectively, and a better activity than the standard oxytetracycline (MIC = 0.5 mg/mL) for E. coli. The MIC values of 36 were 0.125 mg/mL against Escherichia coli ATCC10536, Staphylococcus aureus DSM799, Candida albicans DSM1386, and Aspergillus niger DSM1957 and 0.5 mg/mL against Alternaria alternata CBS1526. Compound 36 was found to be the best inhibitor of C. albicans among the compounds tested, with four times higher activity than the standard cycloheximide. For the fungal strains, 36 showed a lower MIC value and thus higher activity than the standard drug nystatin, overall exhibiting a remarkable antimicrobial activity. Finally, the minimal inhibitory concentration of compound 35 was determined for Escherichia coli ATCC10536, Staphylococcus aureus DSM799, and F. linii KB-F1 and was found to be 0.5 mg/mL for all three strains. Overall, it displayed an equal or poorer performance in comparison to the respective standard drugs and in comparison to other chalcones tested. The MIC values for 35 were higher than its structural analog 34, meaning that the addition of the methoxy group on ring B along with the benzyloxy group does not improve bioactivity but decreases it.
Lastly, values of the minimum inhibitory concentration required to inhibit 80% of cells (MIC80) for compounds 32a-b were determined by Zhang et al. [55]. The compounds were found to be potent against Trichophyton rubrum, with MIC80 values of 0.5 µg/mL each. This value was greater than the standard reference, but 32a-b was among the three most active antifungal agents compared to other chalcones tested.
Sakata et al. [56] synthesized a series of 2-aminochalcones ( Figure 25) and tested their activity against the neurodegenerative Alzheimer's disease markers, namely, acetylcholinesterase (AChE), β-secretase (BACE-1), and the amyloid-β (Aβ). As discussed earlier, some of these compounds have been also reported by other groups. The activities of these compounds against AChE and BACE-1 are shown in Table 13. Tacrine was used a positive control for AChE inhibition, and quercetine was used for BACE-1. Against AChE, all compounds tested showed some inhibition activity, with compounds 27, 30c, 36a, 36b, and 36c showing IC50 values lower than 10 µ M. The 2′,3′-dichloro substituted aminochalcone 30c exhibited the highest potency, with IC50 equal to 0.08 µ M. These compounds were docked into the The activities of these compounds against AChE and BACE-1 are shown in Table 13. Tacrine was used a positive control for AChE inhibition, and quercetine was used for BACE-1. Against AChE, all compounds tested showed some inhibition activity, with compounds 27, 30c, 36a, 36b, and 36c showing IC 50 values lower than 10 µM. The 2 ,3 -dichloro substituted aminochalcone 30c exhibited the highest potency, with IC 50 equal to 0.08 µM. These compounds were docked into the active site of AChE, and it was concluded that the high potency for some of these compounds was due to the hydrophobic features of the analogues as the aromatic ring helped in the adoption of a proper conformation at the ligand cleft. The IC 50 values for BACE-1 inhibition were obtained only for compounds that showed decent percentage inhibition values. Against BACE-1, compound 30c again showed the highest potency (IC 50 = 2.71 µM). Some chalcones without the amino group having structural similarities with compounds in Figure 25 were tested against BACE-1. These chalcones did not inhibit the enzyme, thus showing the importance of the amino group on ring A. The molecular docking studies performed showed that the amino group on ring A interacts with the aspartic acid residues of the catalytic diade of BACE-1. The inhibitory effect on the Aβ amyloid aggregation was determined using thioflavin-T (ThT), which binds to the β-amyloid fibrils. This interaction increases the emission of ThT fluorescence; thus, the presence of an inhibitor will decrease the fluorescence. Aminochalcones 29a, 29, 30c, and 36b showed a good effect against Aβ fibrils formation and reduced the ThT fluorescence emission by 37, 52, 33, and 29%, respectively. The most potent compound was 29, as it was comparable to the reference compound curcumin (inhibition of fibril formation = 56%). Moreover, the cytotoxicity for these 2-aminochalcones was tested against the human glioblastoma M059J, mouse fibroblast Vero, and kidney epithelial 3 T3 cell lines. While 3 T3 was more sensitive to the chalcones, the overall IC 50 values obtained were quite high, showing that they were not potentially cytotoxic. Furthermore, it was determined that these compounds have low water solubility, which might be due to the presence of crystal packing. In conclusion, these compounds are promising leads against AD especially if the hydrosolubility is improved.
Moreover, 2-aminochalcone derivatives with methoxy and other substitutions on ring B ( Figure 26) were synthesized by Zhang et al. [55], who tested the antifungal activity, and Ruanwas et al. [54], who screened them for antioxidant and antibacterial activity. Aminochalcone 37 was tested for antifungal activity against Trichophyton rubrum, and its minimum inhibitory concentration needed to inhibit 80% of cells (MIC80) was determined to be greater than 64 µ g/mL, which was higher than most of the chalcones tested and overall demonstrated that 37 was not a good antifungal agent [55].
2-Aminochalcones 38, 39, and 40 also showed poor antibacterial activity against the grampositive bacteria-Bacillus subtilis, Staphylococcus aureus, Enterococcus faecalis TISTR 459, methicillinresistant Staphylococcus aureus (MRSA) ATCC 43300, and vancomycin-resistant Enterococcus faecalis (VRE) ATCC 51299-and the gram-negative bacteria-Salmonella typhi, Shigella sonei, and Pseudomonas aeruginosa [54]. The MIC values of these compounds for all bacterial strains were ≥300 μg/mL, like compound 26. The low MIC value of the vancomycin standard (<2.34 μg/mL) demonstrates the inadequate activity of the compounds against the strains tested. The antioxidant activities of compounds 38-40 were tested through a DPPH radical scavenging method and were compared to ascorbic acid as a standard reference. The range of the percentage inhibition of free radical scavenging activity of 38-40 was 0.41% to 3.27%, with 38 showing the highest and 39b showing the lowest activity among these compounds. These activities are lower than that of 26 (18.71%) found during the same investigation and significantly weaker than the ascorbic acid reference (92.06% inhibition). The results suggest that the general antioxidant activity by the α,β- Aminochalcone 37 was tested for antifungal activity against Trichophyton rubrum, and its minimum inhibitory concentration needed to inhibit 80% of cells (MIC 80 ) was determined to be greater than 64 µg/mL, which was higher than most of the chalcones tested and overall demonstrated that 37 was not a good antifungal agent [55].
The MIC values of these compounds for all bacterial strains were ≥300 µg/mL, like compound 26. The low MIC value of the vancomycin standard (<2.34 µg/mL) demonstrates the inadequate activity of the compounds against the strains tested. The antioxidant activities of compounds 38-40 were tested through a DPPH radical scavenging method and were compared to ascorbic acid as a standard reference. The range of the percentage inhibition of free radical scavenging activity of 38-40 was 0.41% to 3.27%, with 38 showing the highest and 39b showing the lowest activity among these compounds. These activities are lower than that of 26 (18.71%) found during the same investigation and significantly weaker than the ascorbic acid reference (92.06% inhibition). The results suggest that the general antioxidant activity by the α,β-unsaturated carbonyl group was reduced due to the substituents on ring B in 38-40 [54].
Adding diversity to the plethora of 2-aminochalcones, we will discuss Xia et al.'s [57] prepared derivatives of 2-aminochalcone with substituents on both rings ranging from simple methyl to methylenedioxy substitution ( Figure 27).  Table 14. Compounds 41-44b showed significant cytotoxic activity (ED50 ≤ 4.0 mg/mL) and pronounced selectivity against the KB, KBVIN, and 1A9 cell lines. Compound 42 was more potent than 41 against these cancer cell lines, with notably lower values for the compound concentration, affording a 50% reduction in cell number. However, compound 43, which is a structural analog of 42 and contains a methylenedioxy moiety on ring A (positions 4 and 5), was the most active in this study, with the lowest ED50 values, making it a potential lead for antitumor agents. Among 44a and 44b, only differing in the position of fluorine on ring B, a relatively better activity was shown by 44a and the highest ED50 values; thus, the least potency was displayed by 44b for most of the cancer cell lines. Also, when compared to a similar chalcone only without a -NH2 group at position 2 on ring A, compound 44a was about 40-fold more active, demonstrating the importance of the amino group for biological activity. It was concluded that the introduction of a methylenedioxy moiety on ring A led to enhanced cytotoxic activity compared with the A-ring-unsubstituted compound 42 and that the presence of a methoxy group at position 3 on ring B was beneficial for increased cytotoxicity [57].
The 2-aminochalcone derivative with larger substitutions on ring B was prepared and tested for  Table 14. Compounds 41-44b showed significant cytotoxic activity (ED 50 ≤ 4.0 mg/mL) and pronounced selectivity against the KB, KBVIN, and 1A9 cell lines. Compound 42 was more potent than 41 against these cancer cell lines, with notably lower values for the compound concentration, affording a 50% reduction in cell number. However, compound 43, which is a structural analog of 42 and contains a methylenedioxy moiety on ring A (positions 4 and 5), was the most active in this study, with the lowest ED 50 values, making it a potential lead for antitumor agents. Among 44a and 44b, only differing in the position of fluorine on ring B, a relatively better activity was shown by 44a and the highest ED 50 values; thus, the least potency was displayed by 44b for most of the cancer cell lines. Also, when compared to a similar chalcone only without a -NH 2 group at position 2 on ring A, compound 44a was about 40-fold more active, demonstrating the importance of the amino group for biological activity. It was concluded that the introduction of a methylenedioxy moiety on ring A led to enhanced cytotoxic activity compared with the A-ring-unsubstituted compound 42 and that the presence of a methoxy group at position 3 on ring B was beneficial for increased cytotoxicity [57].
The 2-aminochalcone derivative with larger substitutions on ring B was prepared and tested for antibacterial activity by Nielsen et al. [52] (Figure 28).  Compounds 46 and 47 displayed no significant antifungal activity against Trichophyton rubrum with MIC80 values >64 µ g/mL. This shows that the substitutions on ring B of these compounds are not suitable to inhibit fungal activity, and this might be due to the bulk of the groups as the 2aminochalcones with smaller substituents showed potent antifungal activity [55].

3-Aminochalcone and Derivatives
Approaching the last class of aminochalcones that has a -NH2 substitution on ring A, we introduce 3-aminochalcones and its derivatives with an amine group on position 3 of ring A. In addition to the variety of 4-aminochalcones and 2-aminochalcones, a diverse group of 3aminochalcones including the simplest one was also synthesized by Kozlowska et al. [42] (Figure 30). Compounds 46 and 47 displayed no significant antifungal activity against Trichophyton rubrum with MIC 80 values >64 µg/mL. This shows that the substitutions on ring B of these compounds are not suitable to inhibit fungal activity, and this might be due to the bulk of the groups as the 2-aminochalcones with smaller substituents showed potent antifungal activity [55].

3-Aminochalcone and Derivatives
Approaching the last class of aminochalcones that has a -NH 2 substitution on ring A, we introduce 3-aminochalcones and its derivatives with an amine group on position 3 of ring A. In addition to the variety of 4-aminochalcones and 2-aminochalcones, a diverse group of 3-aminochalcones including the simplest one was also synthesized by Kozlowska et al. [42] (Figure 30). The antiproliferative potential was evaluated on four different human colon cancer cell lines, HT-29, LS180, LoVo, and LoVo/DX, using the Sulforhodamine B (SRB) assay followed by comparison with normal green monkey kidney fibroblast COS7 cells. The activities are summarized in Table 15 as IC50 values. The best activity was observed for compound 48 against the HT-29 cell line and for compound 51 against the LoVo and LoVo/DX cell lines. However, all compounds were cytotoxic against COS7, demonstrating poor selectivity. In general, compounds with ethyl, nitro, and benzyloxy groups at position 4 on ring B represented a group of inhibitors stronger than cisplatin against the HT-29 cell line. For the bioactivity of compound 50 and its analogs 13 and 36, the role of the position of the amine group played a significant role. The strongest inhibition was observed for 2-aminochalcone 36 followed by 3-aminochalcone 50 and then at last 4-aminochalcone 13.
Moreover, the antimicrobial activity of compounds 48-53 tested by Kozlowska et al. [42] is displayed in terms of minimal inhibitory concentration (MIC) values in Table 16.
The growth of E. coli ATCC10536 was prevented to a decent degree by most of the tested aminochalcones with the lowest MIC value shown by 52. Likewise, complete growth inhibition was observed for all these compounds in the case of S. aureus DSM799. Compounds 48, 51, and 53 The antiproliferative potential was evaluated on four different human colon cancer cell lines, HT-29, LS180, LoVo, and LoVo/DX, using the Sulforhodamine B (SRB) assay followed by comparison with normal green monkey kidney fibroblast COS7 cells. The activities are summarized in Table 15 as IC 50 values. The best activity was observed for compound 48 against the HT-29 cell line and for compound 51 against the LoVo and LoVo/DX cell lines. However, all compounds were cytotoxic against COS7, demonstrating poor selectivity. In general, compounds with ethyl, nitro, and benzyloxy groups at position 4 on ring B represented a group of inhibitors stronger than cisplatin against the HT-29 cell line. For the bioactivity of compound 50 and its analogs 13 and 36, the role of the position of the amine group played a significant role. The strongest inhibition was observed for 2-aminochalcone 36 followed by 3-aminochalcone 50 and then at last 4-aminochalcone 13.
Moreover, the antimicrobial activity of compounds 48-53 tested by Kozlowska et al. [42] is displayed in terms of minimal inhibitory concentration (MIC) values in Table 16.
The growth of E. coli ATCC10536 was prevented to a decent degree by most of the tested aminochalcones with the lowest MIC value shown by 52. Likewise, complete growth inhibition was observed for all these compounds in the case of S. aureus DSM799. Compounds 48, 51, and 53 successfully prevented the growth of C. albicans DSM1386, and A. alternata CBS1526 were tested. Compound 51 produced better results than its structural analog 4-aminochalcone 8 against F. linii KB-F1. The overall antimicrobial activity of these compounds is propitious and reveal the significant impact of the position of an amine group on ring A on biological activity [42].
Moreover, the simple 3-aminochalcone 48 ( Figure 30) along with the aminochalcone analogues 1 and 26 were also synthesized by Trein et al. [58] and tested against the parasitic protozoan Trichomonas vaginalis. This flagellate protozoan is the etiological agent of trichomoniasis, a very common nonviral sexually transmitted disease. T. vaginalis is also known to facilitate the transmission of HIV (human immunodeficiency virus) and HPV (human papillomavirus) [59]. Among these compounds, 48 exhibited IC 50 equal to 29 µM, while the simple chalcone and compounds 1 and 26 showed inferior activity. This data corroborates the importance of the presence and position of the amino group on ring A. Moreover, at 29 µM, 48 was also found to affect the growth kinetics of T. vaginalis. However, it was found to be toxic against vaginal epithelial cells HMVII in vitro, with a selectivity index of 0.72. At the same time, injection in the Galleria mellonella larvae indicated that 48 was not toxic to complex living organisms. The researchers tested 48 for its hemolytic effect and ability to induce ROS accumulation in T. vaginalis trophozoites in order to determine the mechanism responsible for this activity. However, the molecular targets remained unidentified. T. vaginalis induces ROS accumulation in cells as part of the immune response. Compound 48 was found to activate ROS production in neutrophils incubated with T. vaginalis, thus enhancing this immune response.
The hydroxy-and dihydroxy-substituted derivatives of 3-aminochalcones ( Figure 31) have also been synthesized and tested for α-glucosidase inhibition by Seo at al. [47]. The IC50 values of 54a and 54b as α-glucosidase inhibitors were >200 µ M each and greater than most of the chalcone derivatives tested in the manuscript and poor in comparison to 4-aminochalcone analogs 4a and 4b, with IC50 values 41 µ M and 62.1 µ M, respectively. According to the study, 54a and 54b only exhibited mild inhibitory activity against β-amylase; hence, they cannot act as reliable lead compounds for such inhibitors [47].
Pati et al. [60] synthesized and studied the cytotoxic properties of several 3-aminochalcones with different methoxy substitutions on both rings A and B (Figure 32). The IC 50 values of 54a and 54b as α-glucosidase inhibitors were >200 µM each and greater than most of the chalcone derivatives tested in the manuscript and poor in comparison to 4-aminochalcone analogs 4a and 4b, with IC 50 values 41 µM and 62.1 µM, respectively. According to the study, 54a and 54b only exhibited mild inhibitory activity against β-amylase; hence, they cannot act as reliable lead compounds for such inhibitors [47].
Pati et al. [60] synthesized and studied the cytotoxic properties of several 3-aminochalcones with different methoxy substitutions on both rings A and B (Figure 32).
The anticancer activity of compounds 55-58 was evaluated against murine melanoma B16 cells via the MTT colorimetric assay, and the IC 50 values are given in Table 17.  The anticancer activity of compounds 55-58 was evaluated against murine melanoma B16 cells via the MTT colorimetric assay, and the IC50 values are given in Table 17. The findings revealed trends in the cytotoxic properties of 3-aminochalcones 55-58. The increase in the number of methoxy groups on ring B showed a marked increase in potency as IC50 values of 57a-c are much lower than that of compounds 56a and 56b. However, this trend is only observable between the mentioned compounds, and compound 58 that has 3-methoxy groups on ring B shows a decreased inhibition compared to other compounds. Overall, 57c was the most potent and 55, without any substituent on ring B, was the least active compound among the 3-aminochalcones tested in this study. This might be due to some positions on ring B being favorable while others being unfavorable to the interactions between the compound and cancer cells [60].
Finally, a 3-aminochalcone with a larger substituent on ring B was reported by Nielsen et al. [52] (Figure 33). The findings revealed trends in the cytotoxic properties of 3-aminochalcones 55-58. The increase in the number of methoxy groups on ring B showed a marked increase in potency as IC 50 values of 57a-c are much lower than that of compounds 56a and 56b. However, this trend is only observable between the mentioned compounds, and compound 58 that has 3-methoxy groups on ring B shows a decreased inhibition compared to other compounds. Overall, 57c was the most potent and 55, without any substituent on ring B, was the least active compound among the 3-aminochalcones tested in this study. This might be due to some positions on ring B being favorable while others being unfavorable to the interactions between the compound and cancer cells [60]. The results reflect the relatively weaker antibacterial potential of 59, the significance of the position of an amine group on ring A, and the possibility of using aminochalcones other than 59 as better leads for antibacterial agents, which brings our evaluation of aminochalcones with the -NH2 group on ring A to a conclusion. The antibacterial activity of compound 59 was tested in terms of MIC values against Staphylococcus aureus ATCC33591 (resistant to methicillin), Enterococcus faecium 17501 (vancomycin-resistant clinical isolate), and Enterococcus faecium ATCC29212, which was 10 µM for each strain. The 2-aminochalcone analog compound 45 showed better antibacterial activity against S. aureus and E. faecium, with MIC values of 5 µM each. The results reflect the relatively weaker antibacterial potential of 59, the significance of the position of an amine group on ring A, and the possibility of using aminochalcones other than 59 as better leads for antibacterial agents, which brings our evaluation of aminochalcones with the -NH 2 group on ring A to a conclusion.

4 -Aminochalcone and Derivatives
Chalcones with amino substitution on ring B have also been synthesized and tested for their bioactivity. Changing the position of -NH 2 from one ring to the other changes the electronics of the compound, which may in turn change the way it interacts with biological targets. Romagnoli et al. [37] prepared a series of 4 -aminochalcones via the Claisen-Schmidt aldol condensation with different substitutions ( Figure 34) and later converted them to their corresponding α-bromoacryloylamido derivatives to compare the cytotoxic activities. In this section, however, we will discuss only the 4 -aminochalcone precursors and their activities, which are shown in Table 18.  As discussed earlier, the simple 4-aminochalcone 1 was also reported in this paper. The IC50 values for 4-aminochalcone are shown in Table 19 in comparison to 4′-aminochalcone.   of compounds 60, 61, 62a-c, 63, 64a, 64b, and 65 As discussed earlier, the simple 4-aminochalcone 1 was also reported in this paper. The IC 50 values for 4-aminochalcone are shown in Table 19 in comparison to 4 -aminochalcone. Evidenced by the IC 50 values, compound 1 has higher antiproliferative activity when compared with 60. Shifting -NH 2 from ring A to ring B decreases the anticancer activity of the chalcone. This observation is also seen in the methoxy-substituted compounds 62a-c and their 4-aminochalcone analogs 3a, 3c, and 3i discussed earlier, where the latter show better activity against all cell lines tested by Romagnoli et al. [37]. 4 -aminochalcone compounds, in general, showed very week antiproliferative activity, as is evident from the high IC 50 values. From the tested compounds, a better activity was shown by 62c, 63, 64b, and 68. Both the methoxy-and ethoxy-substituted compounds showed better activity than the rest. The activity for the methoxy-substituted compounds increased as the substitution on ring A increased.
Some more methoxy-substituted compounds, including 3-aminochalcones, discussed earlier, were synthesized and analyzed by Pati et al. [60]. These compounds included 62c ( Figure 35) and 70 ( Figure 36).  Cytotoxic activity, in the form of IC50 values, for 62c and 70 against the murine melanoma B16 cells was reported to be 30 and >100 µ M, respectively. Thus, neither of these compounds showed significant activity against the cancer cell line. However, it can be concluded that the cytotoxicity increases as the methoxy substitutions increase, as the activity increased threefold with the addition of a methoxy substituent on ring A. They also reported the activity against some 3-aminochalcones with methoxy substitutions including 57c (IC50 against B16 cells = 5.6 µ M), which showed much better activity when compared with 70. The difference in the structures for the two compounds is the presence of the -NH2 group on ring A and an extra methoxy group on ring B for 57c, which increases the cytotoxic activity by almost 18-fold.
The antimitotic activity for 62c and 71 against the HeLa cells was reported to be 0.15 and 0.3 Cytotoxic activity, in the form of IC 50 values, for 62c and 70 against the murine melanoma B16 cells was reported to be 30 and >100 µM, respectively. Thus, neither of these compounds showed significant activity against the cancer cell line. However, it can be concluded that the cytotoxicity increases as the methoxy substitutions increase, as the activity increased threefold with the addition of a methoxy substituent on ring A. They also reported the activity against some 3-aminochalcones with methoxy substitutions including 57c (IC 50 against B16 cells = 5.6 µM), which showed much better activity when compared with 70. The difference in the structures for the two compounds is the presence of the -NH 2 group on ring A and an extra methoxy group on ring B for 57c, which increases the cytotoxic activity by almost 18-fold.
The antimitotic activity for 62c and 71 against the HeLa cells was reported to be 0.15 and 0.3 µg/mL, respectively. A methyl group on the beta carbon decreases the antimitotic activity of the chalcone by half.
Radhakrishnan et al. [62] also synthesized some hydroxy and methoxy 4 -aminochalcone derivatives ( Figure 37) via the Claisen-Schmidt reaction with subsequent reduction to yield the amines from the nitro compounds. They tested these compounds for antityrosinase activity in B16 cells. Since tyrosinase is responsible for melanization in animals, tyrosinase inhibitors are useful for the treatment of such dermatological disorders, especially those associated with melanin hyperpigmentation and sunburn treatment. The tyrosinase inhibition activity in B16 cells was determined for 72-74 by measuring the rate of L-DOPA oxidation. The tyrosinase inhibitions for 72, 73, and 74 were reported to be 75.5 ± 1.12, 54.3 ± 2.01, and 39.6 ± 0.66%. Compound 72 exhibited the most potent tyrosinase inhibition activity (IC50 = 7.82 ± 0.42 µ M), greater than the reference kojic acid (inhibition = 48.4 ± 0.32%; IC50 = 22.83 ± 0.66 µ M). This can be due to the strong electron-donating substituents on the ortho and para positions on the ring B of 72, which influences the electronic structure of ring B. The docking studies done in this investigation showed that these electrondonating groups increase the electron density of ring B through resonance, which results in more effective binding to the active site of the enzyme. While the inhibition for 73 and 74 is less than 72, it is still greater than kojic acid for 73. This change in activity occurs when the phenyl ring is replaced by a naphthyl ring. This suggests that the bulky naphthyl group hinders binding to the active site. These 4′-aminochalcones were concluded to be promising candidates for use as depigmentation agents and in the treatment of dermatological disorders.

3′-Aminochalcone and Derivatives
3′-Aminochalcones are chalcones with an -NH2 group on the 3′ position (on ring B). One such compound with methoxy substitutions on ring A ( Figure 38) was synthesized, and its antimitotic activity was tested by Edwards et al. [61] against the HeLa cell line. Since tyrosinase is responsible for melanization in animals, tyrosinase inhibitors are useful for the treatment of such dermatological disorders, especially those associated with melanin hyperpigmentation and sunburn treatment. The tyrosinase inhibition activity in B16 cells was determined for 72-74 by measuring the rate of L-DOPA oxidation. The tyrosinase inhibitions for 72, 73, and 74 were reported to be 75.5 ± 1.12, 54.3 ± 2.01, and 39.6 ± 0.66%. Compound 72 exhibited the most potent tyrosinase inhibition activity (IC 50 = 7.82 ± 0.42 µM), greater than the reference kojic acid (inhibition = 48.4 ± 0.32%; IC 50 = 22.83 ± 0.66 µM). This can be due to the strong electron-donating substituents on the ortho and para positions on the ring B of 72, which influences the electronic structure of ring B. The docking studies done in this investigation showed that these electron-donating groups increase the electron density of ring B through resonance, which results in more effective binding to the active site of the enzyme. While the inhibition for 73 and 74 is less than 72, it is still greater than kojic acid for 73. This change in activity occurs when the phenyl ring is replaced by a naphthyl ring. This suggests that the bulky naphthyl group hinders binding to the active site. These 4 -aminochalcones were concluded to be promising candidates for use as depigmentation agents and in the treatment of dermatological disorders.

3 -Aminochalcone and Derivatives
3 -Aminochalcones are chalcones with an -NH2 group on the 3 position (on ring B). One such compound with methoxy substitutions on ring A ( Figure 38) was synthesized, and its antimitotic activity was tested by Edwards et al. [61] against the HeLa cell line.
The ED value over 6 h for 75 was 0.15 µg/mL, which is the same as its 4 -aminochalcone analog 62c. Thus, the antimitotic potential for 3 -and 4 -aminochalcones was the same against this cell line.
Along with previously discussed 4 -aminochalcones, Pati et al. [60] also tested the antiproliferative activity of some 3 -aminochalcones ( Figure 39) against the murine melanoma B16 cells. The ED value over 6 h for 75 was 0.15 µ g/mL, which is the same as its 4′-aminochalcone analog 62c. Thus, the antimitotic potential for 3′-and 4′-aminochalcones was the same against this cell line.
Along with previously discussed 4′-aminochalcones, Pati et al. [60] also tested the antiproliferative activity of some 3′-aminochalcones ( Figure 39) against the murine melanoma B16 cells. The IC50 values for 76 and 77 were 0.24 and 2.0 µ M against the B16 cells. This activity is far greater than that of the 3-aminochalcones 55-58, and the 4′-aminochalcones 62c and 70 reported in the same paper suggested the appropriate positioning of the groups. Compound 76 was found to be at least 1000-fold more cytotoxic than compound 58, a 3-aminochalcone with the same substitutions on opposite rings. Between 76 and 77, the cytotoxicity increased with the addition of a methoxy group from 77 to 76. Compound 76 showed the best activity among the compounds reported in the manuscript.
Wang et al. [63] in their paper discussed the synthesis and biological evaluation of 81 ( Figure 41) along with other N-alkyl, N,N-dialkyl, and N-acyl compounds, which will be discussed in the later sections. Like 72-74, compounds 78-80 were tested for their tyrosinase inhibition activity in B16 cells, which was reported to be 63.2 ± 0.12, 49.3 ± 0.45, and 58.5 ± 1.62, respectively. While the activity for these compounds was greater than the reference kojic acid (inhibition = 48.4 ± 0.32%; IC 50 = 22.83 ± 0.66 µM), it was less than their 4 -aminochalcone analogs. Among compounds 78, 79, and 80, compound 78 showed the greatest inhibition (IC 50 = 9.75 ± 1.22 µM) comparative to that of 72, which showed an IC 50 value of 7.82 ± 0.42 µM. In conclusion, in this case, the 4 -aminochalcones exhibited more potent tyrosinase inhibitory activity.
Wang et al. [63] in their paper discussed the synthesis and biological evaluation of 81 ( Figure 41) along with other N-alkyl, N,N-dialkyl, and N-acyl compounds, which will be discussed in the later sections. Compound 81 was studied for their anticancer activity by targeting the tubulin colchicine binding site. Its antiproliferative activity was initially tested against human colon carcinoma cells HCT116 and human hepatocellular liver carcinoma cells HepG2. Compound 81 was found to be the most potent compound among all those tested, and its cytotoxicity was further tested against some cancer cell lines (DU145, B16-F10, MDA-MB-231, A549, and Hela), one normal (LO2) cell line, and one drug-resistant (HCT-8/T) cell line. Table 20 shows the IC50 values for 81 against these cell lines. Colchicine was used as a positive control in this investigation. Chalcone 81 was the most potent compound against almost all cell lines in the manuscript. 1-(4-Methoxynaphthalen-1-yl)ethan-1-one, the naphthyl ketone used to synthesize 81, showed much lower potency. Compound 81 showed potency almost 200-fold greater than colchicine (IC50 = 3.45 ± 0.35 µ M) in prostate cancer cell line DU145. Similarly, in the cervical Hela cancer cell line, the activity of 81 was 100-fold greater than colchicine (IC50 = 8.89 ± 0.68 µ M). The cytotoxicity of 81 was very similar to that of colchicine (IC50 = 5.53 ± 0.92 µ M) for the normal cell line LO2, suggesting its selectivity to be similar to colchicine. Compound 81 was also found to be quite potent against the drug-resistant HCT-8/T cell line, with an IC50 value of 5.33 ± 0.86 µ M, especially when compared to reference colchicine (IC50 = 227.40 ± 95.3 µ M). Compound 81′s tubulin polymerization inhibition was also tested, for which isolated pig brain tubulin was used. The study used five different concentrations of 81 and colchicine and evaluated the tubulin polymerization in vitro. The IC50 values for 81 and colchicine were 7.1 and 9.0 µ M, respectively, which suggests that the molecular target of 81 is tubulin. This study concluded that 81 could serve as a candidate for cytotoxic drugs and tubulin polymerization inhibition.

N-Alkyl and N,N-Dialkyl Aminochalcones
After discussing the numerous -NH2-substituted aminochalcones, with substitutions at multiple positions on both the rings, we shift our gear and look at the aminochalcones that not only contain various functional groups on aromatic rings but also are N-alkyl or N,N-dialkyl. The discussion about Compound 81 was studied for their anticancer activity by targeting the tubulin colchicine binding site. Its antiproliferative activity was initially tested against human colon carcinoma cells HCT116 and human hepatocellular liver carcinoma cells HepG2. Compound 81 was found to be the most potent compound among all those tested, and its cytotoxicity was further tested against some cancer cell lines (DU145, B16-F10, MDA-MB-231, A549, and Hela), one normal (LO2) cell line, and one drug-resistant (HCT-8/T) cell line. Table 20 shows the IC 50 values for 81 against these cell lines. Colchicine was used as a positive control in this investigation. Chalcone 81 was the most potent compound against almost all cell lines in the manuscript. 1-(4-Methoxynaphthalen-1-yl)ethan-1-one, the naphthyl ketone used to synthesize 81, showed much lower potency. Compound 81 showed potency almost 200-fold greater than colchicine (IC 50 = 3.45 ± 0.35 µM) in prostate cancer cell line DU145. Similarly, in the cervical Hela cancer cell line, the activity of 81 was 100-fold greater than colchicine (IC 50 = 8.89 ± 0.68 µM). The cytotoxicity of 81 was very similar to that of colchicine (IC 50 = 5.53 ± 0.92 µM) for the normal cell line LO2, suggesting its selectivity to be similar to colchicine. Compound 81 was also found to be quite potent against the drug-resistant HCT-8/T cell line, with an IC 50 value of 5.33 ± 0.86 µM, especially when compared to reference colchicine (IC 50 = 227.40 ± 95.3 µM). Compound 81 s tubulin polymerization inhibition was also tested, for which isolated pig brain tubulin was used. The study used five different concentrations of 81 and colchicine and evaluated the tubulin polymerization in vitro. The IC 50 values for 81 and colchicine were 7.1 and 9.0 µM, respectively, which suggests that the molecular target of 81 is tubulin. This study concluded that 81 could serve as a candidate for cytotoxic drugs and tubulin polymerization inhibition.

N-Alkyl and N,N-Dialkyl Aminochalcones
After discussing the numerous -NH 2 -substituted aminochalcones, with substitutions at multiple positions on both the rings, we shift our gear and look at the aminochalcones that not only contain various functional groups on aromatic rings but also are N-alkyl or N,N-dialkyl. The discussion about these chalcones will be done like in the previous sections, where we will be discussing the alkylated aminochalcones with the amino group on position 4 of their ring A first.

N-alkyl Derivatives of 4-Aminochalcone
An N,N-dimethylated aminochalcone (Figure 42) was synthesized and tested for its antimitotic activity against the HeLa cell line by Edwards et al. [61]. The ED value over 6 h for 82 against Hela cell line was 0.15 µ g/mL. The reference drug, colchicine (concentration = 0.05 µ g/mL), was 3 times more potent than the tested chalcone. The simple aminochalcone analog for 82 was not tested in this investigation.
Tomar et al. [64] synthesized several piperazine containing chalcones ( Figure 43) via the Claisen-Schmidt condensation reaction and tested their antimicrobial potential. The ED value over 6 h for 82 against Hela cell line was 0.15 µg/mL. The reference drug, colchicine (concentration = 0.05 µg/mL), was 3 times more potent than the tested chalcone. The simple aminochalcone analog for 82 was not tested in this investigation.
Tomar et al. [64] synthesized several piperazine containing chalcones ( Figure 43) via the Claisen-Schmidt condensation reaction and tested their antimicrobial potential. Since piperazine derivatives have been reported to show antifungal activity [65], it was hypothesized that chalcones, with their diverse therapeutic activities, would give potent compounds when coupled with piperazine. Thus, the synthesized compounds were tested for their antibacterial activity against S. aureus 209 p, E. coli ESS 2231, Proteus vulgaris, Klebsiella pneumoniae, and Aspergillus fumigatus. Their antifungal activity was tested against Candida albicans, C. albicans ATCC 10231, and Candida glabrata. The MIC values obtained are summarized in Table 21. Since piperazine derivatives have been reported to show antifungal activity [65], it was hypothesized that chalcones, with their diverse therapeutic activities, would give potent compounds when coupled with piperazine.
Thus, the synthesized compounds were tested for their antibacterial activity against S. aureus 209 p, E. coli ESS 2231, Proteus vulgaris, Klebsiella pneumoniae, and Aspergillus fumigatus. Their antifungal activity was tested against Candida albicans, C. albicans ATCC 10231, and Candida glabrata. The MIC values obtained are summarized in Table 21. Ciprofloxacin was used as the standard drug for antibacterial activity, and fluconazole was used as the standard for antifungal activity. The MIC value for ciprofloxacin against all five bacteria cultures was 100 µg/mL, and fluconazole's MIC value against the three fungi strains was 50 µg/mL. The compounds 84a, 85a, and 87 showed very good activity against S. aureus, and 83, 84a, 85a, and 87 showed very good potency against E. coli. Generally, compounds 83, 84a, 85a, and 87 were found active against all strains. Most of the values were comparable to, if not many folds better than, the reference drugs. Comparing the simple compound with no substitution on ring B, 83 with 87, which has a nitro substitution on the meta position, show that this substitution is well tolerated against S. aureus but not against some other strains such as Proteus vulgaris and Klebsiella pneumoniae. The methoxy substitution causes the activity against S. aureus to increase as well. However, with multiple methoxy substitutions in 85b, the activity decreases. The simple chalcone 83 showed the best activity against all three fungal strains Candida albicans, C. albicans ATCC 10231, and Candida glabrata, which was approximately 10 times greater than fluconazole. Compound 1, the simple 4-aminochalcone, was also tested against a strain of E. coli bacteria and had shown an MIC of 500 µg/mL. Thus, replacing the -NH 2 group with a piperazine ring increases the potency of the chalcone compound. Some more compounds with N-containing rings substituted on position 4 of ring A ( Figure 44) were synthesized by Liu et al. [66] via the base-catalyzed Claisen-Schmidt condensation. Liu et al. [66] tested these compounds for their ability to selectively inhibit P-glycoprotein (Pgp; ABCB1) and breast cancer-resistant protein (BCRP; ABCG2). These proteins belong to the ATPbinding cassette (ABC) family of proteins and are involved in actively flowing anticancer drugs out from their target cancer cells, thus limiting their efficacy. Multidrug resistance (MDR) is a Liu et al. [66] tested these compounds for their ability to selectively inhibit P-glycoprotein (Pgp; ABCB1) and breast cancer-resistant protein (BCRP; ABCG2). These proteins belong to the ATP-binding cassette (ABC) family of proteins and are involved in actively flowing anticancer drugs out from their target cancer cells, thus limiting their efficacy. Multidrug resistance (MDR) is a phenomenon where cancer cells become resistant to anticancer drugs. MDR has been ascribed to overexpression efflux transporters such as Pgp. Pgp inhibition was evaluated by an in vitro calcein-AM assay carried out on Mardin-Darby canine kidney (MDCK) cells, and BCRP inhibition was evaluated by the mitoxantrone (MX) accumulation assay carried out in a human breast cancer cell line (MCF-7). The Pgp inhibition for these compounds was compared with the standard reference verapamil (% calcein accumulation = 188 ± 18). Compound 89 had activity comparable to verapamil, with % calcein accumulation equal to 216 ± 13. In another analysis to evaluate the accumulation of doxorubicin (DOX) in MCF-7 cells, the amount of DOX uptake measured by the level of fluorescence showed that 89, among others, had Pgp inhibitory potential. The investigation to evaluate BCRP showed that tested compounds, including 89, did nothing to increase MX accumulation in the cell line. However, the researchers concluded that, among all of the tested compounds, 89 had the potential to act as a dual inhibitor of Pgp and BCRP, as it was comparable to verapamil in increasing calcein uptake and nearly as equally efficient as fumitremorgin C (FTC) in increasing MX accumulation. Compound 89 also did not display significant cytotoxicity against MCF-7 and HCT116 cells (IC 50 = 16.3 and 13.4 µM respectively), which was a positive observation.
Mishra et al. [67] synthesized fourteen 4-aminochalcones, with alkylation on the nitrogen atom ( Figure 45) via the Claisen-Schmidt condensation method and tested these for their antimalarial activity. In some of these compounds, the N atom was part of an aromatic ring. Piperidine-substituted compound 91, discussed earlier, was also synthesized and tested in this manuscript. The antimalarial activity for compounds 91 and 93-105 depends on their ability to inhibit the parasitic enzyme cysteine protease. The IC50 values against the plasmodial effect of the malarial parasite are shown in Table 22.  The antimalarial activity for compounds 91 and 93-105 depends on their ability to inhibit the parasitic enzyme cysteine protease. The IC 50 values against the plasmodial effect of the malarial parasite are shown in Table 22. All compounds 91 and 93-105 have heterocycles substituted on position 4. Among these compounds, somewhere, the nitrogen atom on position 4 of ring A is bonded with another nitrogen atom. As can be seen from the IC 50 values, within the chloro-substituted compounds, 93, 98, and 99 showed very good antiplasmodial activity, with the triazole substituted chalcone 98 showing the best activity among all. The morpholine-substituted chalcone 96 displayed the lowest activity (IC 50 = 9.1 µg/mL). In methoxy-substituted compounds, inhibition increases with the addition of methoxy groups, as can be seen from the IC 50 values of 100 (monomethoxy) and 103 (trimethoxy). The relationship is unclear when comparing between the compounds with chloro and methoxy substituents on ring B. Comparing between 96 and 104, the activity for the trimethoxy-substituted compound 105 is higher. However, comparing between 98 and 105, chloro-substituted 98 showed better activity. The benzotriazole substituted chalcones 93 and 101 were not very potent. The activity for 98 was better than all the tested compounds. The potency of this compound suggests that nitrogen-containing small lipophilic groups enhance the antiplasmodial activity. Even though other compounds also exist with three nitrogen atoms in the heterocycle, such as 93 and 101, it was presumed that, in 98, the orientation and spacing of the nitrogen atoms in the chalcone allowed it to interact with the histidine residue at the active site of the cysteine protease enzyme. Even though more study needs to be done on these chalcones, they are promising antimalarial agents.
Sharma et al. [68] synthesized some substituted quinolinyl chalcones and quinolinyl pyrimidines. In this review, we will only be discussing the amino-linked quinolinyl chalcones. Figure 46 shows the unsubstituted chalcone and chalcones with methoxy and alkyl substitutions. Figure 47 shows chalcones with heterocycles as ring B and those with chloro-, bromo-, thio-, and nitro-substitutions on ring B.
These compounds 106-117 were tested in vitro for their antitubercular and antimalarial activities by screening the compounds against H 37 Rv strains of the M. tuberculosis and NF-54 strains of P. falciparum. These compounds did not show any significant activity against the malarial strain P. falciparum. In addition to the 4-amino linked quinolinyl chalcones shown in Figures 46 and 47, Sharma et al. [68] also synthesized 4-oxo-linked quinolinyl chalcones. 4-amino-linked chalcones were more active than the 4-oxo-linked ones. Among the 4-amino-linked quinolinyl chalcones, compounds 108a and 108b exhibited a higher activity, with MIC being 3.15 µg/mL against the M. tuberculosis strain. This activity was 16-folds greater than that of pyrazinamide (MIC = 50 µg/mL), a medication used to treat tuberculosis. These dimethoxy quinolinyl chalcones were nontoxic towards the VERO and MBMDM (mouse bone marrow-derived macrophages) cell lines. Moreover, 116a exhibited an MIC of 6.25 µg/mL, which shows that it is active against the M. tuberculosis strain as well.   Amino-linked chalcones with acridinyl group were synthesized by Tomar et al. [69] and tested for their antimalarial activity. The simple aminochalcones were synthesized via the Claisen-Schmidt reaction and then treated with 9-chloroacridine to yield the final chalcones. In addition to the 4-amino-linked chalcones (Figure 48), the authors also reported 3-amino-linked chalcones, which will be discussed in their section. The in vitro antimalarial activity for compounds 118-124 was reported on cultures of the P. falciparum NF-54 strain using chloroquine as the reference drug. In this investigation, Tomar et al. [69] reported the mean number of rings, trophozoites, and schizonts recorded per 100 parasites after incubation for 38 h and the percentage of schizont maturation inhibition at different concentrations of the chalcones. These compounds showed 100% inhibition of schizont maturation at 100, 50, and 10 µ g/mL concentrations. At 2.0 µ g/mL concentration, compounds 119, 120a, and 123 showed no inhibition. Compounds 118 and 120b had 42.8% schizont maturation inhibition. Chalcone 121 showed 85.7%, 71.4%, and 14.3% schizont maturation inhibition at 2.0, 0.4, and 0.08 µ g/mL, respectively. Compound 122 had percent inhibitions of 57.1 and 5.7 against 2.0 and 0.4 µ g/mL concentrations. Compound 124 had an inhibition values of 64.3% against 2.0 µ g/mL and 0% against 0.4 µ g/mL. Among these chalcones, 121 exhibited good antimalarial activity, which is not surprising since it is the methoxy-substituted derivative. However, the potency decreased in the trimethoxy chalcone. Compound 121 was also tested against the chloroquine-resistant rodent malaria parasite The in vitro antimalarial activity for compounds 118-124 was reported on cultures of the P. falciparum NF-54 strain using chloroquine as the reference drug. In this investigation, Tomar et al. [69] reported the mean number of rings, trophozoites, and schizonts recorded per 100 parasites after incubation for 38 h and the percentage of schizont maturation inhibition at different concentrations of the chalcones. These compounds showed 100% inhibition of schizont maturation at 100, 50, and 10 µg/mL concentrations. At 2.0 µg/mL concentration, compounds 119, 120a, and 123 showed no inhibition. Compounds 118 and 120b had 42.8% schizont maturation inhibition. Chalcone 121 showed 85.7%, 71.4%, and 14.3% schizont maturation inhibition at 2.0, 0.4, and 0.08 µg/mL, respectively. Compound 122 had percent inhibitions of 57.1 and 5.7 against 2.0 and 0.4 µg/mL concentrations. Compound 124 had an inhibition values of 64.3% against 2.0 µg/mL and 0% against 0.4 µg/mL. Among these chalcones, 121 exhibited good antimalarial activity, which is not surprising since it is the methoxy-substituted derivative. However, the potency decreased in the trimethoxy chalcone. Compound 121 was also tested against the chloroquine-resistant rodent malaria parasite Plasmodium yoelii (strain N-67) in a Swiss mice model. The authors concluded that these compounds, particularly 121, can be used as antimalarial drugs but that it would be good to first profile these against some normal human cell lines.
Lastly, for our alkylated 4-aminochalcones, compounds 125a and 125b ( Figure 49) were reported by Nielsen et al. [52]. Compounds 125a and 125b were tested for their antibacterial potential against the S. aureus ATCC33591 (resistant to methicillin), E. faecium 17,501 (vancomycin-resistant clinical isolate), E. faecium ATCC29212, and E. coli ATCC25922 bacterial strains. The MICs of 125a against these strains were 10, 10, 20, and 20 µ M, respectively. The MIC for 125b was 10 µ M against S. aureus, E. faecium 17501, and E. faecium ATCC29212. These chalcones were not found to be very potent against bacteria, especially when compared with other compounds tested in the same investigation.

N-Alkyl Derivatives of 3-Aminochalcone
Tomar et al. [69] reported 3-amino-linked chalcones ( Figure 50) and tested these for their antimalarial activity. Compounds 125a and 125b were tested for their antibacterial potential against the S. aureus ATCC33591 (resistant to methicillin), E. faecium 17,501 (vancomycin-resistant clinical isolate), E. faecium ATCC29212, and E. coli ATCC25922 bacterial strains. The MICs of 125a against these strains were 10, 10, 20, and 20 µM, respectively. The MIC for 125b was 10 µM against S. aureus, E. faecium 17501, and E. faecium ATCC29212. These chalcones were not found to be very potent against bacteria, especially when compared with other compounds tested in the same investigation.

N-Alkyl Derivatives of 3-Aminochalcone
Tomar et al. [69] reported 3-amino-linked chalcones ( Figure 50) and tested these for their antimalarial activity. Compounds 126-128 are chalcones with an acridinyl group linked to the position 3 on ring A of the chalcone via the amino group. The in vitro antimalarial activity for these compounds was also tested using cultures of the P. falciparum NF-54 strain, like compounds 118-124. With compounds 126-128, the percent schizont maturation was 100% for 100, 50, and 10 µ g/mL. Compounds 126 and 127 showed percent inhibitions of 97.1% and 71.4% at 2.0 µ g/mL and of 4.3% and 7.1% at 0.4 µ g/mL Compounds 126-128 are chalcones with an acridinyl group linked to the position 3 on ring A of the chalcone via the amino group. The in vitro antimalarial activity for these compounds was also tested using cultures of the P. falciparum NF-54 strain, like compounds 118-124. With compounds 126-128, the percent schizont maturation was 100% for 100, 50, and 10 µg/mL. Compounds 126 and 127 showed percent inhibitions of 97.1% and 71.4% at 2.0 µg/mL and of 4.3% and 7.1% at 0.4 µg/mL concentration. Compound 128 showed no inhibition at 2.0 µg/mL. Among these acridinyl-containing 3-aminochalcones, 127 showed the best activity. Comparing the activity of 127 with the acridinyl-containing 4-aminochalcone 121 discussed earlier, it is evident that the 4-amino-linked analog 121 was more potent. At the 0.4 µg/mL concentration, 121 was 10-folds more active than 127. This observation is in line with the previous observations made when comparing chalcones with amino groups at different positions.
Nielsen et al. [52] synthesized and tested more mono alkylated 3-aminochalcone analogs (Figure 51) of 125 and tested their antibacterial activities. Compounds 129-137 were tested against gram-positive and -negative bacteria, namely, S. aureus ATCC33591 (resistant to methicillin), E. faecium 17501 (vancomycin-resistant clinical isolate), E. faecium ATCC29212, and E. coli ATCC25922. Table 23 shows the MIC.  Compounds 129-137 were tested against gram-positive and -negative bacteria, namely, S. aureus ATCC33591 (resistant to methicillin), E. faecium 17501 (vancomycin-resistant clinical isolate), E. faecium ATCC29212, and E. coli ATCC25922. Table 23 shows the MIC. Mono alkyl aminochalcones 129-132 expressed better antibacterial activity as compared to the latter half of the compounds. Among these, 132 had a better activity for all cell lines. This potent compound has piperazine on ring B, which may contribute to its increased activity because of its basicity and by having a greater degree of protonation. Comparing 129 with 132 shows that the piperazine ring increases the potency of the compound. The biological potency of piperazine-containing compounds was also observed in 83, 89, and related compounds. The reason for the lower activity for the latter half of the compounds was concluded to be the unfavorable orientation of the molecule in the cell membrane. Comparing compounds 137 and 132, the activity for 137 is many folds lower than 132. Similarly, the activity for 134 is lower than that for 133 against the E. faecium 17501 strain. In both of these cases, the activity decreases as the piperazine and phenyl rings on ring B move closer to each other. The authors hypothesized that this could be due to the lipophilic and hydrophilic parts of the molecule coming closer together, making the fusion of these molecules with the cell membrane difficult. However, this trend does not hold when a comparison is made between compounds 136 and 135, where the activity actually increases as the rings move closer. Alkylated 4-aminochalcones (86-92) synthesized by Liu et al. [66] have been discussed in the earlier section. In the same manuscript, three N-alkylated 3-aminochalcones ( Figure 52) were also synthesized and discussed for their ability to selectively inhibit P-glycoprotein (Pgp; ABCB1) and breast cancer-resistant protein (BCRP; ABCG2).  The activity for all three compounds, 138a, 138b, and 139, was not comparable to the reference verapamil or previously discussed 89. Compared to 89, these compounds have an alkylated piperazine ring and the methoxy substitutions are on ring A instead of ring B, which might change the way it interacted with Pgp.

Derivatives of 2-Aminochalcone
Only one alkylated 2-aminochalcone ( Figure 53) was found in the literature. It is an analog of 125 and 129 reported by Nielsen et al. [52] and was tested for its antibacterial activity against the S. aureus ATCC33591 (resistant to methicillin), E. faecium 17501 (vancomycin-resistant clinical isolate), E. faecium ATCC29212, and E. coli ATCC25922 bacterial strains. The MIC for 140 against all four bacterial strains was 10 µ M. The activity for 140 was better than that for the N-alkylated 4-aminochalcone 125. Compounds 125 and 129 showed similar activity against these strains.  The MIC for 140 against all four bacterial strains was 10 µM. The activity for 140 was better than that for the N-alkylated 4-aminochalcone 125. Compounds 125 and 129 showed similar activity against these strains. Nitrogen intermediates such as NO (nitric oxide) play an imperative role in inflammatory reactions of the body. Influencing the expression of enzymes involved in the production of NO and prostaglandin E2 could lead to the development of anti-inflammatory drugs. Rojas et al. [70] tested these nine compounds' inhibition activity in vitro against NO and PGE2 production using the mouse macrophage cell line RAW 264.7. Table 24 shows the inhibitory activity. Nitrogen intermediates such as NO (nitric oxide) play an imperative role in inflammatory reactions of the body. Influencing the expression of enzymes involved in the production of NO and prostaglandin E 2 could lead to the development of anti-inflammatory drugs. Rojas et al. [70] tested these nine compounds' inhibition activity in vitro against NO and PGE 2 production using the mouse macrophage cell line RAW 264.7. Table 24 shows the inhibitory activity. The IC 50 values for only two dimethoxy analog 144b and 144c were determined as they showed percentage inhibition greater than 50%, with IC 50 values 0.7 and 0.6 µM, respectively. The rest of the compounds were inactive. While 144b showed good activity against NO, it was rather poor in inhibiting the production of PGE 2 (%I = 3.5 ± 3.5). Compound 144c was the most potent inhibitor of NO and PGE 2 production; however, it was less potent than the standard drug dexamethasone. It was also found that the dimethylamino-chalcone derivatives 144a-c were not cytotoxic as they did not affect the cellular viability. The addition of methoxy substitutions on ring A increased the potency of the compound. This is an observation that was also made earlier, regarding the potency of the 4-aminochalcone series. All in all, the dimethoxy-substituted derivatives of N,N-dimethyl-4 -aminochalcone, 144b and 144c, can be promising leads to anti-inflammatory agents.

Substitution on Ring
In 1990, Edwards et al. [61] published a paper analyzing almost one hundred compounds for their antimitotic activity. The biggest class of compounds discussed were the 4 -aminochalcones with different methoxy substitutions on their ring A, among other variations. Figure   In addition to the dimethylamino-chalcone compounds, the antimitotic activity of some diethylamino-chalcone compounds was also reported along with two other alkyl substitutions on the amino group at position 4′ ( Figure 57). In addition to the dimethylamino-chalcone compounds, the antimitotic activity of some diethylamino-chalcone compounds was also reported along with two other alkyl substitutions on the amino group at position 4 ( Figure 57).  All compounds 144a, 144c, 143, and 146-162 (Figures 55-57) were tested for their antimitotic activity via an in vitro assay system using HeLa cells. The cell cycle for this asynchronous line is 24 h, and mitosis requires 1 h. Colchicine was used as the reference drug, which stops mitosis at a concentration of 0.05 µ g/mL. The activity for these chalcones was reported as the equivalent dose (ED), i.e., the concentration of the test compound with activity equal to 0.05 µ g/mL of colchicine. The ED values are shown in Table 25. They also determined the irreversibility of the activity for some compounds by treating HeLa cells with the test compounds for 1 h, by washing them, and by subsequently checking the percentage of cells after 24 h, the results for which can be seen in the paper.  All compounds 144a, 144c, 143, and 146-162 (Figures 55-57) were tested for their antimitotic activity via an in vitro assay system using HeLa cells. The cell cycle for this asynchronous line is 24 h, and mitosis requires 1 h. Colchicine was used as the reference drug, which stops mitosis at a concentration of 0.05 µg/mL. The activity for these chalcones was reported as the equivalent dose (ED), i.e., the concentration of the test compound with activity equal to 0.05 µg/mL of colchicine.
The ED values are shown in Table 25. They also determined the irreversibility of the activity for some compounds by treating HeLa cells with the test compounds for 1 h, by washing them, and by subsequently checking the percentage of cells after 24 h, the results for which can be seen in the paper. Table 25. Inhibitory activity of compounds 144a, 144c, 143, and 146- The first alkylated chalcone discussed in this paper, 82, is an N,N-dimethylated aminochalcone ( Figure 42). The dimethylamino group is on ring A instead of B. The analog for 82 in our current discussion is compound 143. The 4 -aminochalcone 143 is 10-fold more active than 82 (ED = 0.15 µg/mL). In these compounds, the groups on both rings are electron-donating. Thus, more electron-donating groups on ring A give better activity. The non-alkylated 4-aminochalcone analog of 143, 62c, was discussed earlier. Its ED value was reported to be 0.15 µg/mL. The dimethylated aminochalone 143 is 10-fold more active than the -NH 2 -substituted analog 62c. Apart from dimethylation, other alkylations were also performed on the nitrogen at position 4 of the chalcone. The N,N-diethyl compound 158a had an ED value of 0.0075 µg/mL; thus, it was twice as potent as 143. However, for the 2,3,4-trimethoxy analogs, 147b and 158b, the relationship is the opposite, with the N,N-dimethyl 4 -aminochalcone 147b being more potent; this may be a result of sterics. The morpholine-substituted chalcone 161 is less active than both 143 and 158a. The ring conformation of the ethyl groups bonded with the electronegative oxygen atom decreases the activity by 830-fold, which is a huge decrease. This shows that the free conformation of N,N-diethyl is crucial for potency. A comparison of 158a and 162 again exhibits the importance of the diethyl group. As can be seen, there are multiple variations of methoxy substitutions on the tested chalcones. The general trend showed that the 3,4,5-trimethoxy-substituted chalcones are more active against the HeLa cell line than their counterparts. Edwards et al. [61] also tested some chalcones with substitutions on their α-carbon atom, shown in Figures 56 and 57. No clear trend was observed while comparing the activities of these compounds. However, they were quite potent with low ED values. The two most potent compounds of the investigation, 152c and 154a (ED value = 0.0038 µg/mL), had bromo and methyl substitutions on α-carbon. The methyl substitution on the β-carbon of the chalcone did not prove to be as successful. Compound 157 had an ED value of >100. Inactivity of 157 can be attributed to the bulky group attached to β-carbon. The inhibition activity may depend on the interaction of HeLa cells with β-carbon. This could also explain why the activity was enhanced upon substitution of α-carbon. Conclusively, the N,N-dialkyl-4 -aminochalcones are superb candidates as antimitotic agents and could be further finetuned to optimize their activity.
Compound 163 (Figure 58) was synthesized by Doan et al. [71] and tested for its antioxidant and antimicrobial activities. Apart from 163, the compounds reported by Doan et al. [71] were methoxy and hydroxy chalcones. Compound 163 did not show any significant antioxidant or antimicrobial activity.
More N,N-dimethyl chalcone compounds considered to be 4-aminochalcone-rivastigmine hybrids ( Figure 59) with substitution on the position 4′ of ring A were synthesized by Xiao et al. [72] and tested for their activity against Alzheimer's disease (AD). Apart from 163, the compounds reported by Doan et al. [71] were methoxy and hydroxy chalcones. Compound 163 did not show any significant antioxidant or antimicrobial activity.
More N,N-dimethyl chalcone compounds considered to be 4-aminochalcone-rivastigmine hybrids ( Figure 59) with substitution on the position 4 of ring A were synthesized by Xiao et al. [72] and tested for their activity against Alzheimer's disease (AD).  Compound 164 is the precursor, as it does not contain the carbamate functionality and rivastigmine, a cholinesterase inhibitor used for the treatment of AD and Parkinson's disease. Multiple factors are involved in the onset and progression of AD, which includes deficits of acetylcholine (ACh), amyloid-β (Aβ) deposits, oxidative stress, and imbalance in the regulation of biometals. Some current therapies to combat AD include treatment with acetylcholinesterase inhibitors (AChEIs), for example, donepezil, rivastigmine, and galanthamine. In addition to this, monoamine oxidase (MAO) inhibitors can act as a potential treatment for AD due to their capacity to inhibit oxidative stress. The high expression of MAO in tissues causes oxidative stress by increasing the level of free radicals. The findings related to the ability of the chalcone analog to inhibit cholinesterase (ChE) and MAO lead these researchers to synthesize a series of chalcone-rivastigmine hybrids. These compounds were tested for their biological activities, namely, inhibition of cholinesterase, antioxidant and metal chelating effects, inhibitory effects on Aβ aggregation and MAO, and the ability to cross the blood-brain barrier (BBB).
The compounds' inhibitory activity was tested against AChE, from the electric eel, and butyrylcholinesterase (BuChE) from rat serum, along with their oxygen radical absorbance capacity (ORAC), summarized in Table 26. None of the synthesized compounds showed any activity towards BuChE. Compound 164 is the precursor, as it does not contain the carbamate functionality and rivastigmine, a cholinesterase inhibitor used for the treatment of AD and Parkinson's disease. Multiple factors are involved in the onset and progression of AD, which includes deficits of acetylcholine (ACh), amyloid-β (Aβ) deposits, oxidative stress, and imbalance in the regulation of biometals. Some current therapies to combat AD include treatment with acetylcholinesterase inhibitors (AChEIs), for example, donepezil, rivastigmine, and galanthamine. In addition to this, monoamine oxidase (MAO) inhibitors can act as a potential treatment for AD due to their capacity to inhibit oxidative stress. The high expression of MAO in tissues causes oxidative stress by increasing the level of free radicals. The findings related to the ability of the chalcone analog to inhibit cholinesterase (ChE) and MAO lead these researchers to synthesize a series of chalcone-rivastigmine hybrids. These compounds were tested for their biological activities, namely, inhibition of cholinesterase, antioxidant and metal chelating effects, inhibitory effects on Aβ aggregation and MAO, and the ability to cross the blood-brain barrier (BBB).
The compounds' inhibitory activity was tested against AChE, from the electric eel, and butyrylcholinesterase (BuChE) from rat serum, along with their oxygen radical absorbance capacity (ORAC), summarized in Table 26. None of the synthesized compounds showed any activity towards BuChE.
A comparison between the activities of 164 and 165 show that the introduction of the carbamate group increases the AChE inhibition by more than 2 folds. The inability of these compounds to inhibit BuChE is a limitation as BuChE is important in regulating the Ach levels during AD. At the same time, the selective inhibition of AChE over BuChE means that these compounds will have less side effects associated with peripheral inhibition of cholinesterase and can also serve as probes for mechanistic investigations. From the N,N-dimethyl-4 -aminochalcones, 164-177, the compounds with cyclic amine groups at the carbamate tail, showed better activity than the linear chains. Compound 167 was the most potent among the lot, as it was twice as active as rivastigmine (IC 50 = 9.94 ± 0.83 µM). Chalcones that were disubstituted with carbamate on ring A at positions 2 and 4, 174-177, had diminished activity as compared to their monosubstituted analog. This could be due to the addition of a bulky group on ring A, which changes the way it interacts with the active site. Some compounds with aminoalkyl groups other than methyl on position 4 of the chalcone were synthesized. These compounds 178-181 were less potent than 167, which shows that the N,N-dimethyl group on position 4 shows the best activity. Substitution of morpholine ring on position 4 (compound 181) caused the activity to decrease by 13-fold when compared with dimethyl and by 6-fold when compared with piperidine. It is possible that the presence of the electron-withdrawing oxygen atom in the ring causes the electron density on nitrogen to decrease, which affects protonation and subsequently the interaction of the compound with the catalytic active site. The results for the antioxidant study on these compounds showed a similar picture where compounds 167, 170, and 173 showed better activity. Replacement of the N,N-dimethyl group on position 4 with other aminoalkyl groups resulted in a significant loss of activity, which shows that the methyl substituents on nitrogen are important for antioxidant potency. The study to investigate the effects of these compounds on Aβ aggregation showed that the simple N,N-dimethyl-4 -aminochalcone 164 as well as the 4-aminochalcone-rivastigmine hybrids have decent Aβ aggregation inhibition activity. It was concluded that the OH on position 2 of ring A was important for potency. The metal-chelating properties and MAO-A and -B inhibition studies were also discussed in that paper. To sum up, the dimethyl substitutions on position 4 nitrogen was important for potency and substituting it with other aminoalkyl groups resulted in decreased activity. Noorulhaq et al. [73] reported the synthesis and antimicrobial studies of new chalcone derivatives, including some with methyl piperazine substitutions on position 4 ( Figure 61). Compounds 182-188 were tested for their antibacterial activity against Escherichia coli, Staphylococcus aureus, Salmonella typhi, and Bacillus subtillis and for their antifungal activity against Aspergillus niger, Aspergillus flavus, Penicillium chrysogenum, and Candida albicans strains, summarized in Table 27 with dimethyl sulfoxide (DMSO) used as the solvent control.  Compounds 182-188 were tested for their antibacterial activity against Escherichia coli, Staphylococcus aureus, Salmonella typhi, and Bacillus subtillis and for their antifungal activity against Aspergillus niger, Aspergillus flavus, Penicillium chrysogenum, and Candida albicans strains, summarized in Table 27 with dimethyl sulfoxide (DMSO) used as the solvent control. "-" denotes "no activity".
Penicillin was used as the standard reference drug for antibacterial activity, and nystatin was used as that for antifungal activity. While none of the compounds performed better than the reference drugs, they still showed good activity with a high zone of inhibition values, especially for 187 against S. aureus and for 184 against A. flavus and A. niger. The potency for these compounds can be attributed to the methylated piperazine substitution on position 4 . The increased activity due to piperazine was observed earlier in the discussion of compounds 83-88 and 132-137.
Apart from all of the other aminochalcones discussed earlier, Liu et al. [66] also synthesized some 4 -aminochalcones ( Figure 62) which were tested for their ability to selectively inhibit P-glycoprotein (Pgp; ABCB1) and breast cancer-resistant protein (BCRP; ABCG2). The activity for the four compounds, 189-191, was not comparable to the reference verapamil or previously discussed compound 89. Compared to 89, these compounds have an alkylated piperazine ring at position 4′ and the methoxy substitutions are on ring A instead of ring B, which probably changes the way it interacts with Pgp.
Compound 137 discussed earlier for its antibacterial activity also has an amino group at the 4′position.

N-Alkyl Derivatives of 3′-Aminochalcone
An N-alkyl-3′-aminochalcone (Figure 63) was synthesized and tested by Edwards et al. [61] for its antimitotic activity against HeLa cells. The activity for the four compounds, 189-191, was not comparable to the reference verapamil or previously discussed compound 89. Compared to 89, these compounds have an alkylated piperazine ring at position 4 and the methoxy substitutions are on ring A instead of ring B, which probably changes the way it interacts with Pgp.
Compound 137 discussed earlier for its antibacterial activity also has an amino group at the 4 -position.

N-Alkyl Derivatives of 3 -Aminochalcone
An N-alkyl-3 -aminochalcone ( Figure 63) was synthesized and tested by Edwards et al. [61] for its antimitotic activity against HeLa cells. The ED value for 192 against HeLa cells was >100 µ g/mL. Comparing this value with the N,Ndimethyl-4′-aminochalcone analog 143 (ED = 0.015 µ g/mL) shows the stark difference in the activity by just changing the position of the dimethylamino group from 4′ to 3′. The meta position on ring B is not favorable for antimitotic potency, possibly because the nitrogen on ring B is not in resonance with the enone-system or for sterical reasons.
Wang et al. [63] tested some N-alkyl-3′-aminochalcones ( Figure 64) for their cytotoxic activities. The ED value for 192 against HeLa cells was >100 µg/mL. Comparing this value with the N,N-dimethyl-4 -aminochalcone analog 143 (ED = 0.015 µg/mL) shows the stark difference in the activity by just changing the position of the dimethylamino group from 4 to 3 . The meta position on ring B is not favorable for antimitotic potency, possibly because the nitrogen on ring B is not in resonance with the enone-system or for sterical reasons.
The antiproliferative activities 193-197 were tested against human cancer cell lines HepG2 and HCT116. Compounds 193-197 are 3 -aminochalcones with alkylation on the amino group on ring B. The ring A for these chalcones is a naphthalene ring with methoxy substitution at the 4 position. The IC 50 values are shown in Table 28. The antiproliferative activities 193-197 were tested against human cancer cell lines HepG2 and HCT116. Compounds 193-197 are 3′-aminochalcones with alkylation on the amino group on ring B. The ring A for these chalcones is a naphthalene ring with methoxy substitution at the 4 position. The IC50 values are shown in Table 28. The in vitro cytotoxic activity for compounds 193-197 against human colon carcinoma cells HCT116 and human hepatocellular liver carcinoma cells HepG2 was determined using the MTT assay. The more potent N-alkyl compound was 196. However, 196 was still 17-fold less active than the non-alkylated 3′-aminochalcone 81, discussed earlier, against the HCT116 cell line (IC50 = 0.28 ±  The in vitro cytotoxic activity for compounds 193-197 against human colon carcinoma cells HCT116 and human hepatocellular liver carcinoma cells HepG2 was determined using the MTT assay. The more potent N-alkyl compound was 196. However, 196 was still 17-fold less active than the non-alkylated 3 -aminochalcone 81, discussed earlier, against the HCT116 cell line (IC 50 = 0.28 ± 0.06 µM) and 26-fold less active for HepG2 cell line (IC 50 = 0.19 ± 0.04 µM).

N-Alkyl Derivatives of 2 -Aminochalcone
Very few N-alkyl-2 -aminochalcones have been reported in the literature. Nielsen et al. [52] synthesized and reported the antibacterial activity of some N,N-dialkyl-2 -aminochalcones ( Figure 65).  Table  29.    Table 29. Compound 201b was the most active among all of them. Potency caused by the presence of the piperazine ring on ring B has been discussed earlier for compounds 131-135. In this case, the potency for 201a and 201b might be due to the presence of the trifluoromethyl group on the phenyl ring at position 5 . The activity drastically decreases for 202 when the phenyl ring is replaced by pyridyl.

N-Alkenyl-Aminochalcones
Dimmock et al. [36] synthesized and tested the cytotoxicity of some N-alkenyl-4-aminochalcones ( Figure 66). Some of these compounds were tested for their cytotoxic activity against human Molt 4/C8 and CEM T-lymphocytes as well as murine P388 and L1210 leukemic cells. The IC50 values are shown in Table 30.  Some of these compounds were tested for their cytotoxic activity against human Molt 4/C8 and CEM T-lymphocytes as well as murine P388 and L1210 leukemic cells. The IC 50 values are shown in Table 30. Since the imine linkage in these molecules is hydrolysable. These compounds tend to present activities similar to the parent compounds. For example, the activities of compound 204, which is more active in the list, displays activities similar to compound 1. The chloro-substituted N-alkenylated chalcones 205 and 206 had low activity except for against the P388 cell line. The simple mono-and dichloro-substituted-4-aminochalcones, 5a and 5e, were almost 50-fold (in some cases, 100-fold) more active against some cell lines (Table 5). This shows that the alkenylation of nitrogen drastically decreased the cytotoxic activity of these chalcones. Similarly, substituting chloro-, methyl-, and methoxy-groups on ring B also led to a decrease in the activity. The anticancer activity of compounds 211-217 against human cancer cell lines in terms of the concentration of compound required for 50% inhibition (IC50) is summarized in Table 31.  The anticancer activity of compounds 211-217 against human cancer cell lines in terms of the concentration of compound required for 50% inhibition (IC 50 ) is summarized in Table 31. The chemistry of the N-acyl-aminochalcones varies from the previously discussed aminochalcones due to the difference in reactivity of the nitrogen-containing groups. In general, N-acylation of the primary amine group of the compounds 1, 5a, 5e, 2, 8, 3a, and 3h to give compounds 211-217 proved to be detrimental to the potencies against the cancer cell lines. It was hypothesized to be due to the polar carboxyl group at the tail, but it would also be a result of the involvement of the lone pair of the N-atom in the newly formed amide bond with the acyl group. The results reveal a decent potency of 215 against murine P388 cells, which sets it apart from other compounds in the series. The potency of 215 is greater than the simple -NH 2 -substituted 4-aminochalcone 8 unlike all other comparisons between the two classes of compounds. Compounds 211-214, 216, and 217 are not promising anticancer agents, evident from their high IC 50 values. In contrast, when compound 213 was tested against another cancer cell line, RPMI-8226, its IC 50 value was found to be 0.112 µM [36]. This value demonstrates the high potency of 213 against this cell line and that it is 53 times more cytotoxic than melphalan. Compounds 211 and 214 were also tested for antifungal activity, but they showed no inhibition against Aspergillus fumigatus and Candida albicans. The activity for N-acyl compounds 211-217 was consistently lower than the N-alkenylated analogs 204-207 and 209. Between the unsubstituted compounds 204 and 211, activity for the N-alkenyl-4-aminochalcone was almost 20-fold higher than the N-acyl-4-aminochalcone against the Molt 4/C8, CEM, and L1210 cell lines.

Substitution on Ring
A simple derivative of N-acyl-4-aminochalcone with hydroxy substitution on ring B was synthesized by Kang et al. [48] (Figure 68). The inhibitory effect of compound 218 was investigated against the action of β-secretase (BACE1), an enzyme strongly correlated with the onset of Alzheimer's disease. However, the IC50 value of 218 was >200 µ M, which was significantly higher than the other aminochalcone derivatives tested. The significant loss in potency was attributed to the acylation at nitrogen in compound 218.
Next, a series of α-bromoacryloylamido chalcones was prepared and tested for antiproliferative activity against several cancer cell lines by Romagnoli et al. [37] (Figure 69). The inhibitory effect of compound 218 was investigated against the action of β-secretase (BACE1), an enzyme strongly correlated with the onset of Alzheimer's disease. However, the IC 50 value of 218 was >200 µM, which was significantly higher than the other aminochalcone derivatives tested. The significant loss in potency was attributed to the acylation at nitrogen in compound 218.
Next, a series of α-bromoacryloylamido chalcones was prepared and tested for antiproliferative activity against several cancer cell lines by Romagnoli et al. [37] (Figure 69). The anticancer activity of compounds 219-223 was tested against six cancer cell lines, which are summarized in Table 32. Overall, compound 222b displayed the highest activity against the cell lines and is the most promising lead molecule of the series. Most of the compounds of this series have markedly better activity than the compounds 211-217, with significantly lower IC50 values. The results of the investigation suggested that the position of the bromoacrylamide moiety on the chalcone is important The anticancer activity of compounds 219-223 was tested against six cancer cell lines, which are summarized in Table 32. Overall, compound 222b displayed the highest activity against the cell lines and is the most promising lead molecule of the series. Most of the compounds of this series have markedly better activity than the compounds 211-217, with significantly lower IC 50 values. The results of the investigation suggested that the position of the bromoacrylamide moiety on the chalcone is important because the activity of compounds 219-223 was found to be better than the compounds with the bromoacrylamide group on ring B tested in the same study [37], which will be discussed later. The compounds 219-223 show very similar activity that did not change much with the changing substitutions on ring B. Thus, the pharmacophore is likely to be the bromoacryloylamido moiety on ring A.
Dominguez et al. [74] synthesized a long series of N-acyl-aminochalcones, with two types of compounds (Figures 70 and 71) and tested their antimalarial potential specifically as inhibitors of in vitro development of a chloroquine-resistant strain of Plasmodium falciparum, the activity of the cysteine protease falcipain-2, and in vitro globin hydrolysis.  Among N-arylurea-aminochalcones 224-256, compounds 234, 237, 239, 240, 242, 253, 255, and 256 showed some decent ability to inhibit parasite development at or below 10 µ M. These compounds were therefore tested against falcipain-2 in terms of their IC50 values shown in Table 33.  M of compounds 234, 237, 239, 240, 242, 253, 255, and 256 against recombinant falcipain-2.  224-256, compounds 234, 237, 239, 240, 242, 253, 255, and 256 showed some decent ability to inhibit parasite development at or below 10 µM. These compounds were therefore tested against falcipain-2 in terms of their IC 50 values shown in Table 33.  of compounds 234, 237, 239, 240, 242, 253, 255, and 256  The activity of compounds in Table 33 was impressive, with compound 242 being the most active against recombinant falcipain-2. Furthermore, compounds that inhibited parasite development were evaluated for the inhibition of globin hydrolysis. Compound 255 was the most active, with 98% inhibition of hemoglobin degradation at 5 µM. Dominguez et al. [74] also tested the ability of the compounds to inhibit hemozoin formation, which showed that compound 255 inhibits hemozoin with IC 50 = 0.73 mM that is more potent than chloroquine (IC 50 = 1.33 mM). The activity of 255 was associated with the presence of 2-pyrrolyl, which replaced the aromatic ring. This structure has a nitrogen-containing heterocycle that resembles the nitrogen of chloroquine. Some N-acyl, nitric oxide-donating, 4-aminochalcone derivatives ( Figure 72) were prepared by Mourad et al. [75] and tested against a wide variety of cancer cell lines for cytotoxic activity. The cytotoxicity of 257a-259 was tested on sixty different leukemia, lung, renal, breast, colon, melanoma, prostate, ovarian, and skin cancer cell lines and reported as the concentration required for 50% maximal inhibition of cell proliferation for cytostatic agents (GI50 values). Among the five compounds, the activities of 257a-b were remarkable against many cell lines. Compound 257a had GI50 values in the range 0.30 µ M to 15.4 µ M for the sixty cell lines, while 257b displayed similarly potent activity, especially against colon cancer cell lines. The furoxan-substituted compounds 258a The cytotoxicity of 257a-259 was tested on sixty different leukemia, lung, renal, breast, colon, melanoma, prostate, ovarian, and skin cancer cell lines and reported as the concentration required for 50% maximal inhibition of cell proliferation for cytostatic agents (GI 50 values). Among the five compounds, the activities of 257a-b were remarkable against many cell lines. Compound 257a had GI 50 values in the range 0.30 µM to 15.4 µM for the sixty cell lines, while 257b displayed similarly potent activity, especially against colon cancer cell lines. The furoxan-substituted compounds 258a and 258b did not show significant cell growth inhibition, while 259 exhibited moderate cell growth inhibition against melanoma UACC-62 (cell growth promotion = 37.53% and inhibition = 62.47%). It was hypothesized that the nature and size of the linker might have contributed to the decreased activity of compounds 258a-259. Overall, the results revealed that the selected NO-donating compounds 257a and 257b exhibited strikingly potent cytotoxic activity against various cancer cell lines, where the maximum inhibitory activity was achieved with nitrate ester 257a. Finally, these novel synthesized NO-donating hybrids denote a significant strategy against cancer that needs further biological studies [75].
Another series of 2-oxo-oxazolidin-3-yl-chalcones was reported by Selvakumar et al. [76] (Figure 73). The antibacterial activities of compounds 260-269b were tested against six bacterial strains and reported as MIC values, shown in Table 34.  The antibacterial activities of compounds 260-269b were tested against six bacterial strains and reported as MIC values, shown in Table 34. Among compounds 260-269b, only compound 267b had antibacterial activity equal to or better than the standard drugs Linezolid and Vancomycin against the bacterial strains tested. Compounds 266-267a and 268a-269b showed moderate activity, and it was observed that, when the fluorine atom was added to ring B of 266 and 268a to give 267a and 268b, the antibacterial activity improved considerably. However, the addition of thiophene and imidazole heterocycles resulted in compounds 265, 269a and 269b that were poor in activity. Interestingly, a change from oxygen to sulfur that led to 267b from 267a engendered an activity by 267b many folds better than its acetamide analog 267a. This gives a promising lead molecule for better antibacterial agents [76].

N-Acyl Derivatives of 3-Aminochalcone
Proceeding the discussion of N-acyl-aminochalcones, some research groups have prepared 3-aminochalcones, with acylation on nitrogen, and tested them for different biological activities. In addition to 4-aminochalcones, Dominguez et al. [74] have also prepared a series of N-arylurea-3-aminochalcones with different substituents on ring B ( Figure 74).
The antimalarial activity of compounds 270-283 in the form of inhibition of in vitro development of a chloroquine-resistant strain of Plasmodium falciparum, of the activity of the cysteine protease falcipain-2, and of in vitro globin hydrolysis was tested following synthesis. Initially, fluorescence-activated cell sorting (FACS) analysis revealed their ability to inhibit parasite development. Selected compounds showed activity including 271 (IC 50 = 2.74 µM), 274 (IC 50 = 2.10 µM), 279 (IC 50 = 2.14 µM), and 283 (IC 50 = 1.76 µM). These selected compounds were then subject to tests for inhibition of globin hydrolysis and only showed mild inhibition of hemoglobin degradation (51-75%), with 279 and 283 performing relatively better than the other two compounds. The authors also thought that para and meta positions in the urea-substituted phenyl ring play an important role in their antimalarial activity, as could be observed for 279 and 283. They concluded that derivative 283 had the best antimalarial properties while its mechanism of action did not appear to be related to hemoglobin hydrolysis or heme detoxification, and compared against compound 255, at the same concentration, 283 was better at stopping the development of P. falciparum in culture (IC 50 = 1.76 µM), but further studies are necessary [74].  Several interesting 2-oxo-imidazol-1-yl-chalcone derivatives were synthesized and tested for antiproliferative activity by Kamal et al. [77] (Figure 75).
properties while its mechanism of action did not appear to be related to hemoglobin hydrolysis or heme detoxification, and compared against compound 255, at the same concentration, 283 was better at stopping the development of P. falciparum in culture (IC50 = 1.76 µ M), but further studies are necessary [74].
Several interesting 2-oxo-imidazol-1-yl-chalcone derivatives were synthesized and tested for antiproliferative activity by Kamal et al. [77] (Figure 75).    Now, we bring our attention to the compounds having an N-acyl group on ring B. The simplest series of such 4′-aminochalcones, 287-296, was prepared by Edwards et al. [61] (Figure 76). Compounds 287-295 are N-acetyl derivatives. The compounds were synthesized by a base-catalyzed Claisen-Schmidt condensation of appropriately substituted aldehydes and ketones. Earlier, we have discussed -NH2-substituted and N-alkyl-aminochalcones from the same investigation. Similarly, the potential of compounds 287-296 as antimitotic agents was tested against HeLa cells. The activity of these compounds was reported as the equivalent dose (ED), which is the concentration of the compound found to be equivalent to 0.05 µ g/mL colchicine. Table 35 represents the ED value of compounds 287-296 over 6 h [61]. Apart from the acetylation on nitrogen at position 4′, compound 62c has the same structure as 293b. Compound 62c has also been added as a reference compound in Table 35. Table 35. The concentration of compounds 287-296 giving the same mitotic index as colchicine (0.05 µ g/mL), i.e., equivalent dose (ED) against HeLa cells exposed to the compounds for 6 h. Earlier, we have discussed -NH 2 -substituted and N-alkyl-aminochalcones from the same investigation. Similarly, the potential of compounds 287-296 as antimitotic agents was tested against HeLa cells. The activity of these compounds was reported as the equivalent dose (ED), which is the concentration of the compound found to be equivalent to 0.05 µg/mL colchicine. Table 35 represents the ED value of compounds 287-296 over 6 h [61]. Apart from the acetylation on nitrogen at position 4 , compound 62c has the same structure as 293b. Compound 62c has also been added as a reference compound in Table 35. Table 35. The concentration of compounds 287-296 giving the same mitotic index as colchicine (0.05 µg/mL), i.e., equivalent dose (ED) against HeLa cells exposed to the compounds for 6 h. Compound 293b acted as an initial lead for the other compounds. Meta-substituted derivatives 287-289 had diminished activity with high ED values. Compounds 293a-c were equipotent in activity and showed the minimum ED values in this compound series. Overall, compound 290 was the most potent among these as an antimitotic agent [61]. Comparing 293b with 62c, it can be seen that the potency decreases with acetylation.

Compound
Romagnoli et al. [37] also synthesized a novel series of α-bromoacryloylamido-chalcones and evaluated them for antiproliferative activity against five cancer cell lines. These compounds included phenyl-containing chalcones and chalcones with naphthalene and a heterocycle instead of the phenyl ring B (Figure 77). Compound 293b acted as an initial lead for the other compounds. Meta-substituted derivatives 287-289 had diminished activity with high ED values. Compounds 293a-c were equipotent in activity and showed the minimum ED values in this compound series. Overall, compound 290 was the most potent among these as an antimitotic agent [61]. Comparing 293b with 62c, it can be seen that the potency decreases with acetylation.
Romagnoli et al. [37] also synthesized a novel series of α-bromoacryloylamido-chalcones and evaluated them for antiproliferative activity against five cancer cell lines. These compounds included phenyl-containing chalcones and chalcones with naphthalene and a heterocycle instead of the phenyl ring B (Figure 77). The results of assays testing the anticancer activity of compounds 297-308 are summarized in Table 36. Compounds 297-308 were designed to assess the structure-activity relationship (SAR) due to different substitutions, both electron-releasing and electron-withdrawing groups, and their positions on ring A. Due to the presence of an α-bromoacryloyl moiety, these compounds were significantly more potent in comparison to the 4 -aminochalcone analog having a -NH 2 group, tested in the same study and shown in Table 18. Compounds 306 and 308 were the more active compounds in the series, which appeared to be due to the thiophene group in the case of 308. Compound 306 appeared to induce apoptosis mediated by the involvement of mitochondria and by the activation of caspase-3. Moreover, a trend was observed for the halogen-substituted compounds 298, 299, 301, and 302, where activity increased in the following order: Br (301) > Cl (299), F (298) > I (302). The addition of another chlorine atom to 299, to give the meta, para-dichloro derivative 300, resulted in about a twofold decrease in the activity. Likewise, a two-fold decrease in activity was observed by shifting the methoxy group from the para (304a) to the meta position (304b) on ring A. On the whole, it was found that the introduction of either electron-releasing (ERG) or electron-withdrawing (EWG) substituents (derivatives 298-306) enhanced antiproliferative activity juxtaposed with the unsubstituted analog 297, and the distinctions between them were not prominent but the greatest improvement in activity seemed to occur with the bulkier substituents 301 and 306. Moreover, these N-acyl compounds showed far greater activity than the simple -NH 2 -substituted chalcones tested by Romagnoli et al. [37]. Thus, it can be concluded that the potency of these compounds is due to the presence of bromoacryloylamido moiety.
Apart from ring A-substituted 4-aminochalcones 260-269b discussed earlier, Selvakumar et al. [76] also prepared and evaluated ring B-substituted N-acyl-4 -aminochalcones ( Figure 78).   All compounds were made via the usual aldol condensation, and compounds 309, 312, and 313 were obtained as inseparable mixture of E and Z isomers. Compounds 310 and 311 had electron-donating groups, while 312-314 had electron-withdrawing groups. The inhibitory effects of these compounds against Staphylococcus aureus ATCC 33591 (methicillin-resistant), Staphylococcus aureus ATCC 49951, Staphylococcus aureus ATCC29213, Enterococcus faecalis ATCC29212 (vancomycin sensitive), Enterococcus faecalis NCTC 12201 (vancomycin-resistant), and Enterococcus faecium ATCC 12202 (vancomycin-resistant) were tested. However, all of them displayed trace or no antibacterial activity with MIC values ≥32 µg/mL for all strains tested. The antibacterial activity of structural analog 260-269b (Table 34) was much better than this series of N-acyl-aminochalcones. Therefore, we can deduce that the location of the N-acyl-amino group matters for antibacterial activity and that the acylated amino group on ring A rather than B leads to better potency [76].

N-Acyl Derivatives of 3 -Aminochalcone
In addition to the N-acyland N-acetyl-amino compounds 287-296, Edwards et al. [61] also prepared a single N-acetyl-3 -aminochalcone ( Figure 79) and similarly tested it for antimitotic activity against HeLa cells. The ED of compound 315 was >100 µ g/mL. This activity was lower than most of the 4′aminochalcone analogs in the series tested, including compound 293b. The meta substitution appeared to be the cause of the drop in the antimitotic activity compared to 293b. Hence, 315 neither is a promising anticancer agent nor leads to further developments [61].
Finally, another set of N-acyl-3′aminochalcone derivatives with substitutions on rings A and B was made and reported by Wang et al. [63] (Figure 80) and evaluated for their antiproliferative activity against HepG2 and HCT116 human cancer cell lines. This investigation also reported the activity for some N-alkylated-3′-aminochalcones 193-197 discussed earlier. The ED of compound 315 was >100 µg/mL. This activity was lower than most of the 4 -aminochalcone analogs in the series tested, including compound 293b. The meta substitution appeared to be the cause of the drop in the antimitotic activity compared to 293b. Hence, 315 neither is a promising anticancer agent nor leads to further developments [61].
Finally, another set of N-acyl-3 aminochalcone derivatives with substitutions on rings A and B was made and reported by Wang et al. [63] (Figure 80) and evaluated for their antiproliferative activity against HepG2 and HCT116 human cancer cell lines. This investigation also reported the activity for some N-alkylated-3 -aminochalcones 193-197 discussed earlier.
The novel compounds 316-321 were analyzed for their in vitro cytotoxicity against human colon carcinoma cells (HCT116) and human hepatocellular liver carcinoma cells (HepG2) using 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay. The IC 50 values of the compounds are shown in Table 37. Compound 193, the non-acetylated 3 -aminochalcone analogue of 316, was also added for comparison. Compounds 316-318 exhibited good cytotoxic activity; however, these activities were still less than that of -NH 2 -substituted 3 -aminochalcone 81. The activities of compounds 319-321 were poor against the cancer cell lines tested. Overall, it was observed that the introduction of normal or branched chain alkyl acyl substituents 316-321 at the amino group of ring B resulted in a decrease in the antiproliferative activity of the aminochalcone; therefore, further studies for appropriate substituents are needed to improve anticancer cancer activity. Compared to the N-alkylated-3 -aminochalcones 193-197, 316-318 exhibited much better activity, which shows that, in this case, acylation on the amino group leads to higher potency as compared to alkylation [63]. The novel compounds 316-321 were analyzed for their in vitro cytotoxicity against human colon carcinoma cells (HCT116) and human hepatocellular liver carcinoma cells (HepG2) using 3-(4,5dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay. The IC50 values of the compounds are shown in Table 37. Compound 193, the non-acetylated 3′-aminochalcone analogue of 316, was also added for comparison. Compounds 316-318 exhibited good cytotoxic activity; however, these activities were still less than that of -NH2-substituted 3′-aminochalcone 81. The activities of compounds 319-321 were poor against the cancer cell lines tested. Overall, it was observed that the introduction of normal or branched chain alkyl acyl substituents 316-321 at the amino group of ring B resulted in a decrease in the antiproliferative activity of the aminochalcone; therefore, further studies for appropriate substituents are needed to improve anticancer cancer activity. Compared to the N-alkylated-3′aminochalcones 193-197, 316-318 exhibited much better activity, which shows that, in this case, acylation on the amino group leads to higher potency as compared to alkylation [63]. Compounds 322-327 were tested for in vitro anticancer activity against human liver cancer cell line HEPG-2. The results are presented in Table 38 in the form of concentration required for 50% inhibition (IC50 values). Compounds 322-327 were tested for in vitro anticancer activity against human liver cancer cell line HEPG-2. The results are presented in Table 38 in the form of concentration required for 50% inhibition (IC 50 values). Among the compounds tested, 322 showed no antiproliferative activity against HEPG-2. Although 326 performed relatively better than 327, both were among relatively more potent compounds in the series. Compounds 326 and 327 were also screened against the cell line after exposure to γ-radiation, and their IC 50 values were reduced to 20.5 µM and 26.8 µM, respectively [78].

N-Sulfonyl Derivatives of 4-Aminochalocone
Kang and coworkers [48] also prepared an elaborate series of sulfonated-4-aminochalcones ( Figure 82) and tested their activities against the β-secretase (BACE1), an enzyme linked to the onset of Alzheimer's disease. Table 39 summarizes the IC 50 values of compounds 322 and 328a-331 against the action of β-secretase (BACE1). Sulfonamide aminochalcones 328b and 329a-d displayed remarkable inhibitory effects against the β-secretase enzyme, with the lowest IC 50 value shown by 329b. Compound 329b was also found to be 70-fold more effective than the corresponding aminochalcone bearing an unsubstituted amine 4b (IC 50 = 17.7 µM). Similarly, 328b showed a markedly enhanced activity in comparison to 4a (IC 50 = 48.2 µM). The inhibition activity was observed to be significantly affected by the position and number of hydroxyl groups on ring B. This is also evident from the relatively poor activity of compound 322, which does not carry a hydroxy group on ring B. A generally better inhibition was observed when the benzenesulfonyl ring had an electron-donating group in the para position; however, the electron-donating potential and size of the substitution also impacted the activity, where smaller groups were better than larger ones. Following this trend, the strongly electron-withdrawing group bearing compounds 328f-g and 329e were the least active inhibitors of BACE1. In addition, the 329-series, bearing a 3,4-dihydroxy group ring B was in general more potent than the corresponding 4-hydroxy derivatives (328a-g). Therefore, these N-sulfonyl-aminochalcones act as valuable lead compounds and are useful in further experimentation and optimization [48].  Compounds 328b and 329b were also synthesized by Kim et al. [79] and tested for inhibition of trans-sialidase from Trypanosoma cruzi (TcTS), a parasite that causes Chagas disease-a disease with a mortality rate as high as 85% and results in interruption of host immune responses, heart disease, and malformation of the intestines. IC 50 values of 328b and 329b were 73 µM and 0.9 µM, respectively. It was suggested that the dihydroxy aromatic moiety present in 329b was a major contributor to the inhibition of TcTS activity.
Seo et al. [47] prepared compounds 328b and 329b along with other aminochalcones and tested their glycosidase inhibitory activities against α-glucosidase, α-amylase, and β-amylase. Compound 329b proved to be the better inhibitor against α-glucosidase with IC 50 = 0.4 µM. These compounds showed noncompetitive inhibition against the enzymes. Compound 328b also showed an impressively low IC 50 value of 0.98 µM promising good inhibition against α-glucosidase. Both the compounds displayed mediocre inhibition against α and β-amylases, with IC 50 values in the range 65 µM to 247.3 µM [47].
In another study, Seo et al. [49] prepared compounds 328a-c and 328e-g and evaluated them for tyrosinase activity and depigmenting ability. The results of the investigation are presented in Table 40. It was found that the 4-hydroxy substitution on ring B was central to the competitive tyrosinase inhibition. Although compounds 328a-c and 328e-g showed slightly lower activities than some other chalcones, the more active compound among these was 328f for tyrosinase inhibition and 328b for melanin formation, respectively. The inhibitor constant, K i , which is the concentration required to produce half-maximum inhibition, indicating the potency of the inhibitor, was also determined for tyrosinase activity, and as predicted by its IC 50 value, 328f had the lower K i value [49].
Moving on, Silva et al. [80] prepared a sulfonamide chalcone derivative with a nitro substituent on ring B (Figure 83). Then, the genotoxic, cytotoxic, antigenotoxic, and anticytotoxic activities of 332 were assessed using the Salmonella typhimurium reverse mutation test (Ames test) and the mouse bone marrow micronucleus test. The Ames test results revealed the potential mutagenic and anti-mutagenic effects of compound 332 at relatively higher doses, whereas the mouse bone marrow micronucleus test uncovered the genotoxic and cytotoxic effects of compound 332, later attributed to the presence of the nitro group. Overall, the results presented a moderate profile of the compound [80].
Lastly, Dominguez et al. [74] reported a series of sulfonamide-chalcone derivatives with different substituents on ring B (Figure 84). Then, the genotoxic, cytotoxic, antigenotoxic, and anticytotoxic activities of 332 were assessed using the Salmonella typhimurium reverse mutation test (Ames test) and the mouse bone marrow micronucleus test. The Ames test results revealed the potential mutagenic and anti-mutagenic effects of compound 332 at relatively higher doses, whereas the mouse bone marrow micronucleus test uncovered the genotoxic and cytotoxic effects of compound 332, later attributed to the presence of the nitro group. Overall, the results presented a moderate profile of the compound [80].
Lastly, Dominguez et al. [74] reported a series of sulfonamide-chalcone derivatives with different substituents on ring B (Figure 84). This group evaluated the antimalarial activity of sulfonamide chalcones 333-343 against cultured Plasmodium falciparum parasites and their effect on inhibition of β-hematin formation in terms of their IC50 values shown in Table 41.  Table 41. Compounds 333-337 and 341 showed no measurable activity against the β-hematin formation. On the other hand, compounds 340, 342, and 343 inhibited β-hematin formation better than chloroquine (IC 50 = 1.33 µM). By a general comparison of 339 and 342, the more active compound in the series, we can observe that, upon going from 2,4-dihydroxy substitution to 3,4,5-trihydroxy substitution on ring B, the inhibitory activity improved significantly. On the other hand, there was no significant inhibition of the development of cultured parasites except for compound 334, which was potent but without any correlation with the inhibition of heme formation. Moreover, the presence of the pyridinyl moiety in 343 seemed to cause considerable improvement in antimalarial activity, which might be due to its resemblance with chloroquine [74].

N-Sulfonyl Derivatives of 3-Aminochalocone
A pair of sulfonated 3-aminochalcone derivatives hydroxylated on ring B have also been made and reported by Seo et al. [47] and Kim et al. [79], shown in Figure 85. Seo et al. [47] tested compounds 344 and 345 for glycosidase inhibitory activity against αglucosidase, α-amylase, and β-amylase. The α-glucosidase activities (IC50 values) of 344 and 345 were 12.4 µ M and 15.6 µ M, respectively. IC50 values of 344 against α-amylase and β-amylase were 37.3 µ M and 201.4 µ M, respectively, and that of 345 against α-and β-amylase were 16.8 µ M and 24.8 µ M, respectively. These results suggested that the activities of compounds 344 and 345 were stronger against all three enzymes, with 345 being the more potent against α-and β-amylases than others. Both 344 and 345 exhibited weaker inhibition than 328b against α-glucosidase. This means that position 3 on ring A for the sulfonamide group is more favorable only for inhibition of α-and βamylases. Overall, the activity of compounds 344 and 345 was much better than other chalcone derivatives assessed [47].
Kim et al. [79] evaluated compounds 344 and 345 for the inhibition of trans-sialidase from Trypanosoma cruzi (TcTS), a parasite that causes Chagas disease. The concentration required for 50% inhibition was found to be 37 µ M and 2.5 µ M for 344 and 345, respectively. Differing comparisons can be drawn for each of the compounds 344 and 345 when put next to their corresponding 4aminochalcone analog 328b and 329b. For monohydroxy substituents like 344 and 328b, a better inhibitory activity was observed by 344; however, strangely for dihydroxy substituents 345 and 329b, the trend was reversed, with 329b showing better activity (IC50 = 0.9 µ M) than 345. Overall, the Seo et al. [47] tested compounds 344 and 345 for glycosidase inhibitory activity against α-glucosidase, α-amylase, and β-amylase. The α-glucosidase activities (IC 50 values) of 344 and 345 were 12.4 µM and 15.6 µM, respectively. IC 50 values of 344 against α-amylase and β-amylase were 37.3 µM and 201.4 µM, respectively, and that of 345 against αand β-amylase were 16.8 µM and 24.8 µM, respectively. These results suggested that the activities of compounds 344 and 345 were stronger against all three enzymes, with 345 being the more potent against αand β-amylases than others. Both 344 and 345 exhibited weaker inhibition than 328b against α-glucosidase. This means that position 3 on ring A for the sulfonamide group is more favorable only for inhibition of αand β-amylases. Overall, the activity of compounds 344 and 345 was much better than other chalcone derivatives assessed [47].
Kim et al. [79] evaluated compounds 344 and 345 for the inhibition of trans-sialidase from Trypanosoma cruzi (TcTS), a parasite that causes Chagas disease. The concentration required for 50% inhibition was found to be 37 µM and 2.5 µM for 344 and 345, respectively. Differing comparisons can be drawn for each of the compounds 344 and 345 when put next to their corresponding 4-aminochalcone analog 328b and 329b. For monohydroxy substituents like 344 and 328b, a better inhibitory activity was observed by 344; however, strangely for dihydroxy substituents 345 and 329b, the trend was reversed, with 329b showing better activity (IC 50 = 0.9 µM) than 345. Overall, the activities of dihydroxy-substituted aminochalcones were much better than monohydroxy substituted aminochalcones, and this sharp difference earned most of the attention in the discussion of results [79].

Concluding Remarks
The focus of this review has been to accumulate aminochalcones in one place and to list their pharmacological activities. During this review, we have attempted to draw comparisons between the biological activities of these aminochalcones. However, a clear trend for the activities between the types of aminochalcones was not observed. Many compounds discussed had activities comparable to, if not better than, the reference drugs against which they were tested. While these investigations have paved a future for the pharmacological significance of aminochalcones, further study is needed to optimize and develop molecules based on these leads. One thing that is clear at this stage is that the pharmacological activities of aminochalcones have not been utilized in the industry as they can be. There is still a molecule to hit the clinical trials. At the same time, there is room to focus on the structure optimization for certain cellular targets. While there have been some reports of the activity of these compounds on microtubules, AChE, BChE, tyrosinase, etc., there is a need to have dedicated drug-discovery programs to optimize the structures, especially considering that covalent inhibitors are an emerging area of drug discovery. We hope that this review will serve as a beacon to provide information about aminochalcones in one place for the scientific community to ponder the reported activities, to design subsequent structure optimizations, and to stimulate further advances in the field.

Conflicts of Interest:
The authors declare no conflict of interest.