2.1.1. Flavonoids
The following 15 different kinds of flavonoids have the most frequently found in licorice (
Table 1), while apigenin (
Figure 2) has received more research attention for its structural changes and antitumor abilities. Following a review of the pertinent literature, it emerged that apigenin’s structural change focused mainly on the following categories:
(1) Etherification: Xiang et al. [
17] used apigenin as raw materials to obtain six apigenin derivatives by introducing methyl ether and difluoromethyl ether at the 7th position of the A ring, difluoromethyl ether at the 4′ position of the B ring, difluoromethyl ether in the 7′ position of the A ring and 4′ position of the B ring at the same time, and bromine atoms at the 6th and 8th positions of the A ring at the same time, and the anti-liver cancer activity of the derivatives was studied in vitro (
Scheme 1). The results showed that compound
3 (6,8-dibromo-7,4-dimethoxy-5-hydroxyflavone) had the strongest anti-liver cancer activity, with a potency 12.09 times that of the lead apigenin and 11.05 times that of the chemotherapy drug 5-FU, and the structure–activity relationship analysis speculated that it may be related to its simultaneous methyl etherification and bromination, and Cardenas et al [
18] also found that the introduction of Cl or Br atoms at the C6 position of the flavonoid A ring can enhance its antitumor activity.
(2) Alkylation: According to Nikaido, T. et al. [
19], the presence of isoprene groups in flavonoids greatly increased their lipophilicity, which can enable compound molecules to exhibit strong affinity for biofilms, which in turn can cause a significant increase in biological activity. The structure of apigenin includes three hydroxyl groups, namely, 4′, 5, and 7, and the activities of the various locations vary. Daskiewicz, J.B. et al. [
20] protected phenolic hydroxyl groups at position 7 and 4′ with chloromethyl methyl ether, phenolic hydroxyl etherification and the introduction of isoprene at position C-5, and then they rearranged σ migration, migrated the 5-position isoprene group to position 8 on the skeleton, and finally deprotected to obtain 8-isoprenylapigenin (
Scheme 2). Activity tests showed that the introduction of isoprene at the 8th position of apigenin could significantly inhibit the proliferation of HT-29 in human colon cancer cells and promote their apoptosis.
(3) Esterification: Aminophosphate is a phosphorus-containing analogue of natural amino acids; the introduction of amino phosphate can often enhance the antitumor activity of the parent drug, and some phosphoramide nitrogen mustard derivatives, such as cyclophosphamide, have been applied because of their good anticancer activity [
21]. In order not to affect the amide bonds and ester bonds in the amino phosphate structure introduced by apigenin, Han, T [
22] chose acetylation under the action of pyridine and acetic anhydride to protect the 4′, 5, and 7 hydroxyl groups, because the hydroxyl group on the 7th position is in the 4-position carbonyl group, the electron-absorbing effect of the carbonyl group enhanced the 7-hydroxyl acidity, so compared with other hydroxyl groups, it was easier to remove the 7-position hydroxyl group, obtain 4′, obtain 5-diacetylapigenin at its 7th position deprotector, and remove 4′. The results show that the five compounds could inhibit tumor cell proliferation to varying degrees, showing good tumor proliferation inhibition activity, especially B (substituent is leucine), D (substituent is alanine), and E (substituent is valine), with better activity, and the IC50 values were 25, 26.2, and 21 μmol/L, respectively, which has certain theoretical and practical significance for the development of drugs for the treatment of cervical cancer (
Scheme 3).
(4) Formation of complexes: Modern research has demonstrated that rare earth metals have unique electronic structures, bonding properties, and high coordination numbers. By forming complexes with naturally occurring substances that have pharmacological activity, these metals can enhance or expand the pharmacological effects of the original ligand, and their toxicity is significantly decreased. Lanthanum nitrate and apigenin were used to create the lanthanum apigenin complex for the first time. The complex’s antitumor activity was tested on the cervical cancer cell line Hela, and the results revealed that it significantly inhibited cell proliferation when the concentration was higher than 30 ug/mL. The inhibitory impact grows over the same period of time as the compound concentration increases; at the same concentration point, the inhibitory effect rose as the complex’s action duration grew longer. It has greater biological activity than the ligand apigenin [
23] (
Scheme 4).
2.1.2. Flavonols
Currently, licorice contains mostly the following eight flavonols (
Table 2), and in the study of structural modification of its antitumor components, galangin (
Figure 3) and quercetin (
Figure 4) have been reported more.
Fields of exploration into galangin’s structural change are outlined in the following order:
(1) At position 8, nitrogenous basic groups are inserted: With galangin as the starting material, Luo, Y et al. [
29] introduced several nitrogen-containing heterocyclic compounds at the 8th position of its structure through the Mannich reaction (
Scheme 5). The product’s antitumor activity was then evaluated using the MTT method, and the results shown that compound
2c and
2d had substantially higher proliferative inhibitory activity than galangin (IC50: 11.37 and 13.57 μmol/L) on human prostate cancer PC-3M. It was concluded that the addition of galangin 8-position nitrogenous heterocycles may be responsible for the augmentation of derivative activity after compound
2d’s proliferation inhibitory activity on human colon cancer LOVO cell lines had been raised 5.22-fold.
(2) Introduction of substituents at positions 3, 5, 7: Zhao, L et al. [
30] conducted research on the effect of hindering the proliferation of human myeloid leukemia K562 cells through the inclusion of benzyl, acetyl, isopropyl, and trifluoromethyl substituents at positions 3, 5, and 7 of galangin to synthesize 12 derivatives (
Figure 5). It turned out that when the 3-position hydroxyl group of galangal was benzylated, the activity also fell significantly when the 3rd and 7th hydroxyl groups of the parent nucleus underwent benzyl substitution, showing that the retention of the 7-position hydroxyl group was crucial for activity. However, more research on the structure–activity correlations is required because there are not many structural modifiers.
Additionally, studies have shown that quercetin in licorice has chemopreventive and antitumor effects, and it has inhibitory effects on human prostate cancer [
31], breast cancer [
32], lung cancer [
33], lymphoma [
34], ovarian cancer [
35], and other malignant tumor cells; however, because quercetin is a planar molecule, its spatial structure is relatively tightly stacked, and it is not easily dispersed by solvents or solutes, making its water solubility poor (<7 μg/mL); this affects its pharmacokinetic properties, and the bioavailability after entering the human body is low (the peak plasma concentration is only 0.13~7.60 μmol/L) [
36], thereby restricting the clinical use of quercetin as an anticancer medication, making its structural modification of particular importance. To summarize the study development of structural modification of quercetin in antitumor in recent years, the following three aspects are mainly considered:
(1) Hydroxyl esterification: Because quercetin has a total of five hydroxyl groups, its hydroxyl groups are typically selectively esterified. Mulholland, P. J et al. [
37] and Golding, B. T et al. [
38] used quercetin as a launching material, using it in different positions of hydroxyl groups to react differently, selectively maintaining hydroxyl groups to obtain compound
4, and then adjusting it with ethyl isocyanatoacetate to obtain compound
5. The synthesis of QC12 is shown in
Scheme 6. After compound
5, dehydroxyprotector undergoes ester hydrolysis under acidic conditions to produce 3′-(N-carboxymethyl) carbamoyl-3, 4′, 5, 7-tetrahydroxyflavone (QC12), the derivative introduces glycine groups to increase its water solubility. Informal phase I clinical trials demonstrate that QC12 can inhibit the growth of human ovarian cancer A2780 cells and block cell proliferation in the late S stage and early G2, making it a new water-soluble anti-cancer lead compound (
Scheme 6).
(2) Hydroxy ether formation: Liu, Q. et al. [
39] used rutin as the starting material, followed by the Williamson ether reaction, amidation reaction, and Pd/C catalytic hydrodebenzyl to produce 13 quercetinamide derivatives (
Scheme 7). When this series of derivatives was tested for antitumor activity, the results revealed that the antitumor activity had increased, with compound
7–
13 having the greatest inhibitory effect on human esophageal squamous cell carcinoma cells EC109 (IC50 = 10.25 μmol L
−1) was significantly superior to the parent drug quercetin (IC50 = 31.884 μmol·L
−1) and 5-FU (IC50 = 41. 738 μmol·L
−1).
(3) Formation of metal complexes: Quercetin is a particularly powerful metal chelating agent that can coordinate with a variety of metal ions to form complexes owing to its distinctive planar chemical structure, the presence of hydroxyl groups, and the presence of carbonyl groups. In relation to research by Ksenija et al. [
40], quercetin lanthanum complexes have a potent cytotoxic effect on human cervical cancer cell lines (Hela) at concentrations between 100 and 1000 mmol mL
−1 when exposed for a duration of three hours. Low-dose complexes will have the same biological effect on tumor cells without the negative side effects associated with high drug concentrations, making them potential antitumor medications.
2.1.3. Isoflavones
Isoflavones are important components in licorice, with phytoestrogen activity, which can inhibit the proliferation of a variety of cancer cells. Now, more licorice isoflavones have been discovered, primarily the following 37 compounds (
Table 3), and the structural alteration of their antitumor components, formononetin (
Figure 6) and genistein (
Figure 7), is being researched more.
As an important class of antitumor drugs, nitrogen mustard derivatives are the general term of β-chloroethylamine compounds, including mono β-chloroethanamine and bis β chloroethanamine [
61]. At present, the synthesis is relatively simple, the cost is low, and there are many nitrogen mustard drugs that have been used in clinical practice, but there are still shortcomings such as large adverse reactions, low treatment efficiency, poor selectivity, etc. Hu, K et al. [
62] produced 15 nitrogen mustard derivatives of frmononetin with frmononetin as the mother in a straightforward five-step reaction involving nitrification, phenolic hydroxyetherification, reduction, amino substitution, and chlorine substitution. He then tested the target compounds’ effects on the human cancer cell lines HCT-116, DU-145, Hela, and SGC-7901 for their ability to inhibit tumor growth, and in vitro antitumor activity experiments showed that compound
6d had a significant effect on HCT-116 cells, and its IC50 was 3.80 μmol/L, which was stronger than that of the parent drug manganthocyanin (IC50 = 60.97 μmol/L) and the positive control mephalan (IC50 = 20.90 μmol/L), respectively. And, the results can be inferred that the introduction of formononetin in the 7-position hydroxyl group and nitrogen mustard in the 3′ position can enhance the inhibitory effect on tumor cells (
Scheme 8). In order to create two novel NO donor-type anthocyanin derivatives, Xin, F et al. [
63] connected NO donor fragments on 7-position phenolic hydroxyl groups using the design principle of synergistic prodrugs (
Scheme 9).
Likewise, genistein has been highly regarded by the medical community in many different nations as a preventive agent for tumor cells because it has the advantage of not destroying normal cells. Although genistein has a significant first-pass effect and weak lipophilicity and hydrophilicity, this makes it difficult to reach the goal of therapeutic therapy of disorders due to limited bioavailability. As a result, its structure has undergone various changes to increase bioavailability. The following three aspects are where the structural change is currently concentrated.
(1) Modification of 7-position hydroxyl groups: Based on the lipophilicity and biodegradability of the derivatives, Polkowski, K et al. [
64] synthesized an assortment of genistein glycoside derivatives (
Figure 8). Studies on the survival of cells in cultivation and cytotoxicity have revealed that hydrophilic glycosides have substantially lower anticancer activity than free glycoside ligands. However, compared to genistein, lipophilic glycosides exhibit a markedly stronger anticancer activity. On the tumor cells Balb/c3T3, Popiołkiewicz’s [
65] lipophilic genistein derivatives had a minimum inhibitory concentration of 5 mol/mL, which was a factor of ten lower than genistein’s.
(2) Structural modification of 4′-position hydroxyl group: By adding nitro to the 4′-position of the genistein backbone, Jin, Y et al. [
66] constructed genistein nitro derivatives (
Figure 9). Results highlighted that, with the exception of the parent compound nitrogenitrin, which exhibited strong antitumor activity, the antitumor effects of the other compounds were less potent than those of the mother compound. It was also evident that the isoflavones’ 7-position hydroxyl group may be the active essential component.
(3) Structural modification of 2 or 3 hydroxyl groups: Zhang, L et al. [
67,
68] synthesized more than 50 derivatives of genistein, and they tested the antitumor activity in vitro, in which the 7- and 4′ hydroxyl groups were replaced with ethoxycarbonylformyl groups in all derivatives; the results showed that the antitumor activity had the lowest IC50 (8.5 μmol/L), which was higher than that of the positive control 5-fluorouracil (IC50 = 13.4 μmol/L), which indicated that the replacement hydroxyl group introduced a lipophilic group. It can significantly improve the antitumor activity and lipophilicity of genistein derivatives.
2.1.4. Chalcones
At the moment, there are 24 different types of chalcones (
Table 4) found in licorice. While researching the structural modifications of these compounds that make them antitumor active, many researchers discovered that isoliquiritigenin (
Figure 10) is connected by two benzene rings, A and B, through the cross-conjugation of propenone. The connected bridge has three atoms, thus facilitating a large degree of selection freedom and a large spatial range of induction fit with the receptor.
Methoxy, -methyl, aryl, and 2′-oxygen-containing groups can be appended to its A ring for boosting its anti-mitotic activity [
73,
74]. Also, Ma, Y [
75] added 10 Mannich groups (
Scheme 10) to the A ring 3′-methyl position of 3′-methy lisoliquiritigenin, including dimethylamine, morpholine, cyclohexane, and diisopropylamine. Experiments in mice confirmed that the inhibition rate exceeded than that of isoglycyrrhizin, with diisopropylamine derivatives having the highest inhibition rate. The inhibition rate of isoliquiritigenin S180 tumor cells at 180mg·kg
−1 was 71.68%. Yang, X et al. [
76] and Xu, F et al. [
77] discovered that isoliquiritigenin analogues prevented the spread of human cervical cancer cells and that they all had a clear pro-apoptosis effect on SiHa and HeLa cells at a dosage of 100 μg/mL. Activity was increased by adding a single methoxy or hydroxyl group to the isoliquiritigenin B ring’s third position. Although still powerful, the activity of the reduction of one hydroxyl group in the second position of the A ring is less than that of isoliquiritigenin. One hydroxyl group’s activity was decreased at the second position of the A ring, one hydroxyl group was added to the third position of the B ring, and one methoxy group’s activity was added to the fourth position, showing that the hydroxyl groups had been added. It was demonstrated that 3-methoxy isoliquiritigenin had a better apoptotic impact than isoliquiritigenin in the experiments on averting the proliferation of human liver cancer Bel-7402, and the highest possible apoptosis rate could reach 93.5% and 85%, respectively (
Scheme 11).