Twenty five flavonoids were measured simultaneously in the aerial parts of nineteen Cephalaria species ^[54][56]. The authors found that the main flavonoids in the studied plants were 5 (0.05–5.47 mg/g), 9 (0.01–7.65 mg/g), 13 (0.01–4.45 mg/g), 14 (0.02–4.91 mg/g), hesperidin (25, 0.11–29.79 mg/g), cyanidin-3-O-glucoside (28, 0.07–20.59 mg/g), and astragalin (kaempferol-3-O-glucoside, 2, 0.16–9.27 mg/g). The other flavonoids identified in this study were 1 (0.01–0.44 mg/g), 7 (0.13–0.60 mg/g), 12 (0.01–1.33 mg/g), nicotiflorin (kaempferol-3-O-rutinoside, 3, 0.19–1.06 mg/g), guiaverin (quercetin-3-O-arabinoside, 10, 0.11–0.72 mg/g), luteolin-7-O-rutinoside (16, 0.03–0.61 mg/g), diosmetin (luteolin 4′-methyl ether, 18, 0.01–0.28 mg/g), nepetin (6-methoxyluteolin, 19, 0.01–1.26 mg/g), acacetin (5,7-dihydroxy-4′-methoxyflavone, 24, 0.02 mg/g), genistein (4′,5,7-trihydroxyisoflavone, 26, 0.18 mg/g), penduletin (4′,5-dihydroxy 3,6,7-trimethoxyflavone, 27, 0.01 mg/g), pelargonidin chloride (29, 0.06–0.65 mg/g). Moreover, the highest flavonoid content was found in the aerial parts of C. tchihatchewii Boiss. (from 0.08 to 29.79 mg/g). The extract of C. davisiana contained secondly high level of flavonoids (from 0.02 to 14.78 mg/g). Besides that, the most abundant flavonoids—25 (29.79 mg/g) and 28 (20.59 mg/g) were detected in C. tchihatchewii among all studied species.

In the latest study from 2020, Chrząszcz et al., reported that the aerial parts of C. uralensis contained 9 (0.86 μg/g of dry extract), 20 (41.71–65.18 μg/g of dry extract) and 21 (1.87–4.67 μg/g of dry extract), and the flowers—15 (7.91–40.19 μg/g of dry extract), 20 (48.50–51.72 μg/g of dry extract) and 21 (4.20 μg/g of dry extract). Moreover, in the aerial parts of C. gigantea 15 (80.45–115.10 μg/g of dry extract), 20 (79.15–108.42 μg/g of dry extract) and 22 (2.15–2.98 μg/g of dry extract) were identified using LC-DAD-MS/MS method [27].

2.2. Phenolic Acids

Phenolic acids are a large group of phenolic compounds in plants, that include two groups—hydroxybenzoic (C₆-C₁ structures; e.g., gallic, p-hydroxybenzoic, protocatechuic, syringic) and hydroxycinnamic (C₆-C₃ structures; e.g., caffeic, ferulic, synapic) acid derivatives with various number and position of methoxylation and hydroxylation in aromatic ring. In plants, these compounds exist in their free and bound forms, and more often bound forms occur as their glycosides and esters ^[57][59]. Phenolic acids have a crucial for plants growth and reproduction, and they are produced as a response to environmental factors (e.g., light) and to defend injured plants ^[59][61]. What is more, they are reported to have a wide spectrum of pharmacological activities including antioxidant ^[60][62], antibacterial ^[61][63], anti-inflammatory ^[62][64], and anticarcinogenic ^[57][59] activities.

To date, there are only a few reports regarding the occurrence of phenolic acids of the Cephalaria genus. The most frequently identified phenolic acid is caffeic acid (36), which was found in the roots of C. gigantea ^[42][57][42,59], aerial parts (0.84–1.27 μg/g of dry extract) and flowers (0.79–0.91 μg/g of dry extract) of C. uralensis [18] and in the aerial parts of eighteen species (0.01–4.27 mg/g) collected in the Anatolia area (Turkey) [46].

In the aerial parts of C. gigantea chlorogenic acid (30, 101.79–135.83 μg/g of dry extract), cryptochlorogenic acid (31, 16.02–20.80 μg/g of dry extract), neochlorogenic acid (32, 5.13–9.35 μg/g of dry extract), 3,5-O-dicaffeoylquinic acid (33, 73.53–118.90 μg/g of dry extract) and 4,5-O-dicaffeoylquinic acid (34, 11.57–13.43 μg/g of dry extract) were detected [27], and in the roots of this species 30 and 36 was identified ^[42][57][42,59]. Moreover, the authors found that higher concentration of phenolics (phenolic acids and flavonoids) was contained in the ethyl acetate fraction from the roots of C. gigantea than in the aqueous fraction ^[42][57][42,59].

Chrząszcz et al. [27] identified in the aerial parts and flowers of C. uralensis 30 (114.90–132.18 and 94.90–98.75 μg/g of dry extract, respectively), 31 (1.68–4.01 and 7.45 μg/g of dry extract, respectively), 32 (3.87–8.75 and 3.42–8.54 μg/g of dry extract, respectively), 33 (58.35–70.26 and 41.29–48.30 μg/g of dry extract, respectively), and 34 (8.07–17.81 and 7.18–7.65 μg/g of dry extract, respectively).

Ali and co-authors [17] investigated different C. syriaca parts and they described the occurrence of 30, syringic acid (42) and vanillic acid (43) in the shoots, gallic acid (38), p-hydroxybenzoic acid (39), sinapic acid (41), 42 and 43 in the seed, and 39 in the roots.

Three hydroxycinnamic esters—30, 3,4-di-O-caffeoylquinic acid (35) and 33—were isolated from the roots of C. ambrosioides collected in Athens (Greece). All these compounds were identified using spectral data ^[58][60].

2.3. Antioxidant Activity

Most of the antioxidant potential in plants is caused by the redox properties of phenolic compounds that make it possible for them to act as hydrogen donors, reducing agents, and singlet oxygen quenchers. Their antioxidant activity is a result of different mechanisms such as free radicals scavenging, metal ion chelation, reduction, oxidase inhibition, as cofactors of enzymes catalyzing oxidative reactions, free radical stabilization and radical chain reaction termination ^[60][63][64][62,65,66].

The antiradical activity of the flavonoids isolated from the flowers of C. pastricensis was evaluated using the 1,1-diphenyl-2-picrylhydrazyl (DPPH) radical scavenging assay. It was found that cynaroside (14) and luteolin 7-O-arabino(1 → 6)glucoside (17) in different concentrations (5–80 μM) possess significant antiradical activity with EC₅₀ = 41.3 μM and 41.4 μM, respectively [36].

The antioxidant activity of compounds isolated from the aerial parts of C. isaurica, C. paphlagonica, C. scoparia, and C. stellipilis was evaluated using the DPPH radical scavenging and CUPric Ion Reducing Antioxidant Capacity (CUPRAC) methods. The authors found that isoorientin was the most effective antioxidant compound in both the DPPH (IC₅₀ = 0.119 ± 0.0004 mg/mL, while for ascorbic acid was 0.01 ± 0.002 mg/mL) and CUPRAC (6.683 ± 0.636 mmol TRg⁻¹) assyas, with a value comparable to Trolox and ascorbic acid used as the positive controls [43]. Isoorientin is well known antioxidant and its structure-activity relationship is well documented ^[43][65][43,67].

Kirmizigül et al., evaluated n-hexane extracts of C. davisiana, C. elazigensis, C. paphlagonica and C. stellipilis from different regions of Turkey, using the CUPRAC assay, for the cupric (II) reducing antioxidant capacity, were 0.334, 0.252, 0.136 and 0.120 mmol TR/g dry extract, respectively. It seems that antioxidant activity of these species resulted from synergistic effect of ALA and phytol. The extracts exhibited a high antioxidative activity of 0.334–0.120 mmol TR/g dry extract. C. davisiana was the most effective cupric (II) reducer ^[66][68].

Sarıkahya and co-authors tested also the hexane extracts of ten Cephalaria species (C. anatolica, C. aristata, C. aytachii, C. elazigensis var. elazigensis, C. hirsuta Stapf, C. taurica, C. tuteliana, C. procera, C. speciosa, C. tchihatchewii) for their antioxidant capacity using the DPPH radical scavenging and CUPRAC methods. The DPPH tests revealed that hexane extracts of C. tchihatchewii, C. hirsuta, C. anatolica, C. elazigensis var. elazigensis and C. speciosa have significant radical scavenging activity, with the IC₅₀ values of 3.77 ± 0.67, 5.13 ± 1.04, 5.20 ± 0.92, 5.28 ± 0.46 and 6.17 ± 3.13 mg/mL, respectively. The highest TEAC value (1.005 mmol ± 0.13 TE/g extract) they found for C. aristate and its reducing power was related to phenolic content (2.91 ± 0.15 mg GAE/g extract). The authors concluded that DPPH scavenging potential of Cephalaria extracts may be attributed to their phenolic compounds, that could donate electrons to DPPH. Because in the CUPRAC method, the reactive -OH groups of phenolic antioxidants are oxidized to the corresponding quinones and Cu(II)-bis(neocuproine) is reduced to the chelate, Cu(I)-bis(neocuproine), the correlation between CUPRAC values and phenolic contents of C. tchihatchewii, C. aristata and C. speciosa in this study is consistent with the above phenomenon [45].

Mbhele et al., evaluated various extracts (acetone, ethanol, methanol, hydroethanol and water) of the leaves and roots of C. gigantea by means of three different assays, including the DPPH radical test, 2,2′-azinobis[3-ethylbenzthiazoline]-6-sulfonic acid (ABTS^•+) decolorization test, and the ability to reduce FeCl₃ solution. Water extract from the leaves and roots possessed the lowest IC₅₀ (0.6 and 2.8 μg/mL, respectively) in the DPPH assay. Hydroethanolic extract from the leaves had the lowest IC₅₀ for both ABTS radical scavenging (1.0 μg/mL) and reducing activity (1.7 μg/mL). The water and hydroethanolic extracts of both leaves and roots of C. gigantea contained the highest amounts of phenolics and flavonoids and this suggest that these compounds could be responsible for their strong antioxidant activity [28].

The antioxidant activity of a C. jopponsis aqueous, ethanolic and ethyl acetate extracts were evaluated in vitro (phosphomolybdenum method) [38]. The studied extracts showed antioxidant activity ranging from 20.7 to 41.1 mg of ascorbic acid/g dry extract. Furthermore, Rahimi and co-authors ^[67][69] studied the effect of various fertilizers on the antioxidant activity of C. syriaca and they concluded that the antioxidant capacity (DPPH assay) of the studied samples was ranging from 47.10–60.16%.

Kavak and Baştürk [34] analyzed the antioxidant activity of the seeds of C. syriaca collected from different areas in Turkey. They found that studied extracts possessed DPPH inhibition activity ranging from 18.8 to 67.3%. Moreover, the ABTS results (TEAC values) were demonstrated values from 9.8 to 41.8 mmol Trolox eq/g DW.

The antioxidant activity of the oil extracted from the seeds of C. syriaca was evaluated by Atalan et al. ^[68][70]. The authors found that in the DPPH^• test, plant extracts did not have a high activity. The highest value was observed at 70 μL/mL concentration and it was 9.27 μL/mL while the percent of DPPH inhibition by ascorbic acid (used as a standard substance) was 83.75 μL/mL.

The antioxidant effect of C. gigantea and C. uralensis extracts were evaluated in vitro using DPPH^•, ABTS^•+ and metal chelating assays. The higher DPPH^• scavenging activity was found for the aerial parts of C. uralensis (IC₅₀ = 2.86 ± 0.12 mg/mL). The extract from the flowers of C. uralensis demonstrated the highest scavenging free radical effect in the ABTS^•+ (IC₅₀ = 0.45 ± 0.21 mg/mL). The extracts from the aerial parts of C. uralensis were also the most active ones interfering with the formation of iron and ferrozine complexes, that suggest their high chelating capacity [27]. The main compounds identified in these extracts were chlorogenic acid (30), isoorientin (20) and swertiajaponin (15), the compounds which are well-known natural antioxidants showing strong effects in different tests ^[69][71].

2.4. Conclusions and Research Gaps/Future Investigations

This review summarizes the phenolics contain and antioxidant activity of species of the Cephalaria genus. According to literature information, only 29 species of the genus have been studied so far, and the available data are still fragmentary and insufficient. Moreover, the state of knowledge of Cephalaria species contains some gaps, which require more investigation.

So far, in the Cephalaria species, only 43 compounds belonging to the phenolic acids and flavonoids classes have been identified. Kaempferol, luteolin and quercetin and its derivatives have been the major constituents found in the investigated species. What is more, most of phenolic compounds they were detected using old, not very precise methods. Thus, it would be advisable to reexamine Cephalaria species for the presence of these compounds using modern analytical methods.

It seems to be interesting to combine these results with those of a chemotaxonomic study to see if there is any correlation between chemical profile and molecular and/or morphological features.

All the abovementioned findings suggest that an obvious gap in our knowledge about the Cephalaria genus also concerns their antioxidant activity. The research carried out so far has shown that these plants have a strong antioxidant potential. Thus, a focused investigation of the other species, and compounds isolated might be helpful to identify possible uses of these plants in the pharmacology, food or cosmetic industries.