1. Introduction
Pumpkin and squash are common dish ingredients in South America, China, southern Asia, and Japan. They are also used in North American cuisines and are well known in Western Europe. However, in the central and eastern European countries they became partly forgotten and mainly associated with puree juice and soup for the youngest children.
These vegetables belong to the
Cucurbita genus and they are among the oldest domesticated plants, used as early as ca. 10,000 B.P. [
1] on the territory of contemporary Mexico and Guatemala, predating corn and beans by more than 4000 years [
1,
2]. In the 16th century they were introduced in Europe [
3,
4] and since then rapidly spread worldwide [
5]. Cucurbitaceae family consists of more than 900 species and
Cucurbita comprises 14 species with six subspecies and two wild varieties [
6,
7]. The family contains also cucumbers, gourds, melons, watermelons, chilacayotes, and others. The cultivated cucurbits are quite similar in terms of their requirements for growth and development but their fruit morphology (sizes, shapes, colors, pulp structure) is highly variable [
2]. Cucurbits are known to reveal wide range of medicinal properties and therefore are recognized as a functional food [
8,
9,
10]. A number of their biologically active compounds were investigated for cytotoxic, hepatoprotective, anti-inflammatory, and cardiovascular properties [
11]. For that reason, they may also be regarded as healthy food for healthy aging. It has to be realized that the aging society requires substantial changes in both the nutrient demands and ways of alimentation. It also brings numerous chronically ill patients and leads to increased incidence of comorbidities including hypertension, atherosclerosis, cardiovascular disease, age-related eye diseases, obesity, type II diabetes, neurodegenerative disorders, and cancer.
The group of the elderly (65+ years old) is growing rapidly and for people aged 80+ their population is predicted to exceed 400 million by 2050 [
12]. In 1999, the first “Modified Food Guide Pyramid” for adults aged 70+ was proposed [
13]. It was constructed assuming that the narrower base reflects a decrease in energy needs, while emphasizing the importance of nutrient-dense foods, dietary fiber, and water. In addition, nutrient-specific supplements appropriate for older people, e.g., deeply colored fruits and vegetables were recommended. It was highlighted that they should be consumed as a whole fiber-rich food [
13]. Recent studies based on HEI-2015 (Healthy Eating Index) [
14,
15] revealed a positive trend in the nutrition of older Americans. On the contrary, research on the diet of older inhabitants of Switzerland showed that only 38% of this group complied with “The Swiss Food Pyramid” indicating a need for lifelong education in this area [
16]. Building social awareness of specific dietary needs of the elderly has become an urgent and challenging task for researchers and physicians.
All parts of Cucurbitaceae plants are edible and therefore they are grown for seeds, flowers, roots, leaves, and fruits. Flowers (of squash and pumpkins) and roots (of chayote) are ingredients in traditional cuisines [
17]. Seeds can be consumed raw or roasted, and may also serve as material for cooking oil, rich in biologically active compounds [
18]. In several world regions,
C. pepo seeds are used in traditional medicine to cure urinary and prostate diseases or as anti-inflammatory, antipyretic, and analgesic remedies. Their antioxidant and lipoxygenase inhibitory activities are well documented [
19]. Fruits, in turn, are used when collected at various stages of maturity and can be cooked, baked, pickled, candied or consumed raw. Infusions and decoctions made of
Cucurbita fruits in traditional medicine are believed to alleviate cold and ache [
11,
17,
20,
21]. Note that cucurbits are easily digestible and have soft and delicate textures, which are the features especially important for seniors, particularly the ones with masticatory/swallowing dysfunctions and/or special nutrition needs [
12]. The treatment with
C. pepo fruit pulp extract showed an increase in alkaline phosphatase activity and mucosal thickness which confirmed its gastroduodenal protective and anti-ulcerogenic properties [
22]. Pumpkin is considered as a good source of anti-inflammatory substances found helpful in many diseases such as arthritis [
23,
24].
Cucurbita fruits are rich in phenolic compounds: protocatechuic, chlorogenic, salicylic,
p-hydroxybenoic,
p-cumaric acids, eriodictyol-7-neohesperidoside, and hesperidin [
25]. Foods rich in polyphenols, in particular flavonoids, were shown to modify endothelial formation of NO and to improve endothelium function in humans [
26]. Polyphenols were also found to positively influence neuronal cells by attenuating oxidative stress and damage in Alzheimer’s and Parkinson’s diseases as well as in amyotrophic lateral sclerosis [
27]. Clinical manifestations of many neurodegenerative diseases are associated with ageing; however, the onset of neuronal death progresses through life [
28].
Most of anti-cancer properties of
Cucurbita concern seeds and seed oil; however, several studies revealed anti-carcinogenic potential of fruit-borne compounds.
Cucurbita polysaccharide named PPPF directly induced apoptosis of HepG2 cells due to down-regulation of the signal transduction pathways, and this mechanism was proposed to facilitate the development of a therapeutic strategy for treating human hepatoma [
29]. Cucurbitacins are triterpene secondary metabolites shown to induce apoptosis of various cancer cell lines [
17,
30] and to arrest the cell cycle at the G2/M phase [
31,
32]. Note, however, that the role of numerous antioxidants including polyphenols found in
Cucurbita fruits, in anti-tumor action is still unclear.
Yellow to dark-orange colors of
Cucurbita fruits result from high content of carotenoids, mainly β-carotene and/or lutein as well as zeaxanthin [
33,
34,
35]. These carotenoids play an essential role in maintaining ocular health status [
36]; β-carotene is a precursor of 11-
cis retinal, a chromophore of rhodopsin found in rods, receptors enabling vision under low-light conditions. Lutein and zeaxanthin are the main antioxidants of retina, absorbing UV radiation and blue light as well as scavenging free radicals and reactive oxygen species (ROS). The oxidative stress caused by the mentioned radiation contributes to the aging processes resulting, among others, in eye diseases such as age-related macular degeneration (AMD) and cataract [
36]. Prevention and treatment of age-related eye diseases includes carotenoid supplementation.
The common feature of the
Cucurbita pulp is its low content of fat (about 2.3% in
C. pepo) [
21] and low glycemic index due to the high content of dietary fiber, especially pectins [
37]. Cucurbits were shown to reduce the need for insulin in diabetic patients [
38]. Many studies confirmed the hypoglycemic efficacy of various polysaccharides found in the pulp [
39,
40]. Furthermore, the research on animal and human models revealed that treatment with some pumpkin extracts, e.g.
C. moschata, had hypoglycemic and other anti-diabetic effects as well as stimulated regeneration of pancreatic β-cells [
41,
42].
C. ficifolia (fig-leaf gourd) was even listed within a group of the best anti-obesity medicinal plants due to ability to reduce systemic chronic inflammation accompanying obesity [
43]. The results obtained upon the consumption of cucurbit fruits were comparable with those of commonly prescribed anti-diabetic drugs [
41].
This study was aimed to assess the antioxidant potential and other health-beneficial properties of fruits of 18 cultivars of four species: Cucurbita maxima Duchesne, C. pepo L., C. moschata Duchesne, and C. ficifolia Bouché successfully planted under temperate climate conditions of central Europe. The research is expected to expand current knowledge on the health-promoting potential of Cucurbita fruits, especially in the context of dietary requirements of the elderly as well as patients suffering from chronic diseases.
2. Results
The highest content of total phenolic compounds (TPC, expressed as chlorogenic equivalents, CAE, in mg per 100 g of fresh weight) was found in the fruits of
C.moschata ‘Kogigu’ (70.8 mg) (
Table 1). That cultivar was also characterized by the highest contents of the following phenolics (given in mg per 100 g of fresh weight): protocatechuic (2.42 mg), syringic (16.41 mg) and ferulic (0.442 mg) acids, catechin (0.52 mg), and kaempferol (0.107 mg). High level of protocatechuic acid was also found in the fruits of ‘Shishigatani’ (1.70 mg) (
Table 2 and
Figure S1).
Among the analyzed C. maxima cultivars, ‘Indomatrone’ and ‘Bambino’ were characterized by a substantially high level of total phenols—i.e., 50.4 and 41.6 mg—respectively. In addition, ‘Indomatrone’ fruits contained one of the highest levels of salicylic acid (2.56 mg), comparable only to the value noted for ‘Table Gold’ of C. pepo (2.74 mg). On the other hand, three of the analyzed cultivars, i.e., ‘Chicago Warted Hubbard’, ‘Garbo’, and ‘Triamble’ contained significant amounts of catechin.
For C. pepo, the highest levels of total phenolics were noted in the fruits of ‘KamoKamo’ (51.5 mg) and ‘Sweet Dumpling’ (48.1 mg) cultivars. The latter one was also characterized by high accumulation of syringic acid (7.70 mg). The content of total as well as individual phenolic compounds in the fruits of C. ficifolia ‘Angel Hair’ was at a relatively low level.
The highest concentrations of β-carotene (between 12.5–14.6 mg 100 g
−1f.w.) (
Table 1) were found in the fruits of ‘Indomatrone’, ‘Australian Butter’, ‘Chicago Warted Hubbard’ (
C. maxima), ‘Sweet Dumpling’, and ‘Table Gold’ (
C. pepo) as well as ‘Kogigu’ and ‘Shishigatani’ (
C. moschata). Fruits of ‘Musquée de Provence’ (
C. moschata) and ‘KamoKamo’ (
C. pepo) contained the lowest levels of that carotene among all analyzed cultivars—i.e., 0.5 and 1.9 mg 100 g
−1f.w.—respectively.
The analysis of the antioxidant potential of
Cucurbita fruits revealed significant differentiation with respect to both the tested cultivar and applied assay (
Table 1). The highest values of antioxidant capacity measured by all three assays and expressed as Trolox equivalents, TE, per 100 g of fresh weight were obtained for ‘Hokkaido’ (
C. maxima) and ‘Angel Hair’ (
C. ficifolia). Interestingly, pumpkin fruits of ‘Indomatrone’ (
C. maxima) were characterized by high values of FRAP (85.2 TE) and CUPRAC (256.6 TE) but revealed an exceptionally low antioxidant capacity as measured by the DPPH assay (1.01 TE). Conversely, ‘Musquée de Provence’ (
C. moschata) fruits exhibited relatively high DPPH values (16.08 TE) and low antioxidant potential as measured by FRAP (31.9 TE) and CUPRAC (86.1 TE) assays when compared to other cultivars. Fruits of ‘Sweet Dumpling’ (
C. pepo) produced substantially high antiradical scavenging activity (32.10 TE). The lowest values of antioxidant capacity as measured by all three methods were documented for: ‘Butternut’ (
C. moschata), ‘Halloween’ (
C. pepo), and ‘Garbo’ (
C. maxima).
Correlation matrix was constructed to analyze the relation between the content of selected compounds exhibiting antioxidant properties and the values of antioxidant capacities for all the analyzed cultivars (
Table 3). A positive correlation between the content of total phenolic compounds and antioxidant capacity as measured by FRAP (
r = 0.46 *) and CUPRAC (
r = 0.54 ***) methods was revealed. Contrarily, the content of catechin was negatively correlated with FRAP (
r = −0.54 ***) and CUPRAC (
r = −0.44 *) values of pumpkin fruits. Interestingly, the negative relation was also found for concentration of β-carotene (as well as salicylic acid) and antiradical scavenging activity (
r = −0.65 *** and
r = 0.53 ***, respectively). The content of syringic acid was positively correlated with that of protocatechuic acid (
r = 0.64 ***) and total phenols (
r = 0.78 ***). High value of correlation coefficient for the antioxidant capacities measured by FRAP and CUPRAC (
r = 0.89 ***) confirms the similarity of the tested methods with respect to the mechanism of action.
The analysis of the content of selected macro- and micronutrients (given per 100 g of fresh weight) revealed substantial diversity between the tested cultivars (
Table 4). The ‘Indomatrone’ cultivar (
C. maxima) revealed the highest accumulation (per 100 gf.w.) of most mineral nutrients, namely: K (469.8 mg), Mg (34.0 mg), S (49.3 mg), Na (6.82 mg), Fe (0.47 mg), and Mn (103.5 mg). At the same time, this cultivar contained relatively low level of B (0.15 mg). Fruits of ‘Sweet Dumpling’ and ‘Table Gold’ of
C. pepo contained significant amounts of Mg, P, Na, and Fe, while that of ‘Halloween’ (the same species) were particularly rich in calcium (38.0 mg). ‘Kogigu’ (
C. moschata) fruits were characterized by the highest accumulation of Cu (148.4 µg) as well as of K, P and S. The cultivars containing the lowest levels of mineral elements were ‘Angle Hair’ (
C. ficifolia), ‘Bambino’ (
C. maxima), and ‘Miranda’ (
C. pepo). Interestingly however, in the fruits of ‘Bambino’ a relatively high content of Ca was measured (32.3 mg).
The highest concentration of total soluble sugars (expressed per 100 g of fresh weight) (
Table 1) was determined in the fruits of ‘Bambino’ (7.89 g), ‘Indomatrone’ (7.34 g), and ‘Chicago Warted Hubbard’ (7.34 g) cultivars belonging to the
C. maxima species. For the case of
C. moschata, only ‘Kogigu’ tended to accumulate high amounts of sugars (6.71 g). The lowest levels were found for ‘Sweet Dumpling’ and ‘Halloween’ (
C. pepo).
The content of amino acids also showed substantial differences between the analyzed Cucurbitaceae species and cultivars (
Table 1). The highest values (in mg per 100 gf.w.) were noted for
C. maxima cultivars ‘Hokkaido’ (109.5 mg) and ‘Indomatrone’ (71.3 mg), while the lowest for ‘Musquée de Provence’ (7.6 mg,
C. moschata), ‘Angel Hair’ (13.0 mg,
C. ficifolia) and ‘Sweet Dumpling’ (12.7 mg,
C. pepo).
The analyzed cultivars were grouped according to their antioxidant and nutritional qualities upon hierarchical cluster analysis (HCA) (
Figure 1). The main goal of this attempt was to classify the objects into clusters according to their similarity. Note however, that the employed method did not make it possible to obtain clusters homogenous for individual species of the
Cucurbita genus.
In the further step, the principal component analysis (PCA) was performed to identify the main sources of variability between the analyzed cultivars with respect to their nutritional qualities (
Figure 2). The PCA analysis was applied to mean values and allowed extraction of five principal components with eigenvalues above 1 that accounted for 84.39% of the variability of 21 tested parameters (
Table 5). The first principal component (PC1) accounted for 39.12% of the total variance and integrated the content of most mineral elements (Cu, Fe, K, Mg, Mn, Na, P, S, Zn) as well as the total phenolics (
Table 6). PC2 (14.26% of total variance) was mainly negatively correlated with the content of salicylic acid. The third principal component (PC3) explained 13.36% of the variance and was positively correlated with the content of amino acids as well as the antioxidant activity as measured by the FRAP method. In turn, PC4 was moderately negatively correlated with the antioxidant capacity measured with all three methods and positively correlated with the content of syringic acid, yet the loading factor did not exceed |0.7|. Finally, PC5 was negatively related to the content of B.
A scatter plot of the score values attributed to the genotypes projected to PC1 and PC2 failed to provide a clear distinction between the analyzed
Cucurbita species based on the analyzed nutritional and antioxidant parameters. It was mainly because relatively small percentage of variance (53.38%) was explained by the first two principal components (
Figure 2). However, most of the tested
C. maxima cultivars grouped closely with the exception of ‘Indomatrone’. The significant distance of that cultivar from the origin and from other tested genotypes is mainly related to significant accumulation of the analyzed mineral elements, as well as of salicylic and syringic acids as described above. These results indicate high intraspecies variability in
Cucurbita genus regarding the accumulation of health-promoting compounds and the antioxidant capacity.
3. Discussion
Polyphenols are plant secondary metabolites with high antioxidant capacity. Their activity is determined by direct reaction with free radicals, scavenging of free radicals and singlet oxygen, reactivity as hydrogen- or electron-donating agents, capability of reacting with other antioxidants, ability to produce new generation of antioxidant-derived radicals, and by the potential of chelating transition metals [
44,
45].Phenolic compounds occur widely in fruits, vegetables, herbs, and beverages [
46,
47,
48,
49]. From among the tested
Cucurbita pulps, the Japanese ‘Kogigu’ (
C. mochata) cultivar was extraordinary in terms of the total phenolic content; it contained the highest amount of these compounds (70.8 CAE 100 g
−1f.w.). For syringic acid, the ‘Kogigu’ fruit accumulated this compound three times as much as the second in order ‘Shishigatani’ of the same species. In addition, ‘Kogigu’ contained the most protocatechuic acid and the flavonoids: catechin and kaempferol. The other cultivar with the elevated content of several phenolic acids was
C. maxima cv. ‘Chicago Warted Hubbard’; its fruits revealed the highest concentrations of
p-hydroxybenzoic, and
p-coumaric acids among all the tested fruits, and were the second to accumulate ferulic and caffeic acids.
Biological activity of
p-coumaric, caffeic, and ferulic acids are quite similar. They are synthesized via the shikimate pathway where
p-coumaric acid is converted into caffeic acid by hydroxylation, whereas the latter one forms ferulic acid upon methylation [
50]. The antioxidant potential of these compounds depends primarily on the number of hydroxyl and methoxy groups attached to the phenyl ring [
51]. Antioxidant capacities of a series of phenolic acids and flavonoids were earlier measured by Rice-Evans et al. [
44]. Based on their work, the antioxidant power of phenolic acids identified for
Cucurbita fruits in our study can be arranged in the following order:
p-coumaric > ferulic > syringic > caffeic > protocatechuic > salicylic >
p-hydroxybenzoic acids. In turn, according to Kikuzaki et al. [
52], the radical DPPH scavenging activity decreased in the order: caffeic acid > ferulic acid >
p-coumaric acid. In our study, the contents of
p-coumaric and caffeic acids in all samples were relatively low, while the contents of ferulic acid varied significantly upon the tested cultivar. The fruits of ‘Kogigu’ (
C. moschata), ‘Garbo’, and ‘Chicago Warted Hubbard’ (
C. maxima) contained the highest amounts of ferulic acid. Cucurbits are known as rich sources of this polyphenol compared to other fruits and vegetables; only some leguminous vegetables and tomatoes were shown to accumulate it to a greater extent [
53]. Ferulic acid is known to exert anti-angiogenic and anti-tumor effects by affecting the activity of vascular endothelial growth factor (VEGF), platelet derived growth factor (PDGF) and hypoxia-inducible factor 1 (HIF-1) [
54]. It can also inhibit skin photo-aging and therefore has been used as a component of cosmetic preparations [
53]. Salicylic acid was also detected in the examined
Cucurbita fruits. Notwithstanding its moderate antioxidant capacity, this compound is widely known to reduce the risk of myocardial infarction and ischemic stroke. Although its content in cucurbits is much lower than e.g., in raspberries, the pumpkin pulp can still provide continuous supplementation in this phenolic compound due to the long storage time and the substantially larger resources available for food processing.
Two flavonoids: catechin and kaempferol were detected in most fruit pulps. Flavonoids are efficient antioxidants with well-pronounced health-beneficial properties. They can protect against oxidative-stress based diseases and are able to modulate enzyme activities as well as interactions with specific receptors. Their comprehensive mode of action includes quenching of free radicals, chelating metals, suppressing the enzymes associated with free radical generation, and stimulation of internal antioxidant enzymes [
55]. Protective action of flavonoids against cardiovascular diseases was confirmed, which was based—among other mechanisms—on decreasing the oxidation rate of low-density lipoproteins [
56]. Kaempferol has recently focused special interest and is currently considered as a potential cancer treatment agent because of its strong capacity to reduce the oxidative stress [
57,
58]. Note that, although in the commonly consumed vegetables (e.g., onions) and in several herbs, kaempferol may occur in concentrations much higher than in pumpkin, the size of a single serving of a pumpkin dish is significantly larger and therefore may provide considerable and biologically-significant quantities of this health-beneficial compound.
The obtained results indicate that
Cucurbita vegetables contain relatively low amounts of phenolics, especially when compared to richer sources such as berries or grapes [
46,
59]. However, the level of phenolic compounds in selected
Cucurbita cultivars was comparable to those noted for potatoes (36.9–52.7 mg 100 g
−1f.w.) [
60] and carrots, with the exception of purple cultivars (24.2–40.4 mg 100 g
−1f.w.) [
61]. Additionally, the pulp of selected
Cucurbita cultivars, such as ‘Indomatrone’ or ‘Sweet Dumpling’ can be considered as a richer source of essential mineral nutrients such as: Cu, Zn, and Mg as compared to the mentioned two other crop species [
62,
63].
It should be emphasized that the abundance of phenolic compounds does not necessarily imply high total antioxidant potential of any biological sample. The antioxidant properties of
Cucurbita may also result from the presence of carotenoids which are usually assumed to play a predominant role in this respect. However, the pumpkin pulp was also found to be rich in vitamins C and E [
64,
65] as well as in carbohydrates, which all might add to the resultant activity. The abovementioned facts imply that it is very difficult to estimate the total antioxidant power only based on the content of particular bioactive compounds. This conclusion gave reasons to launch direct measurements of antioxidant (CUPRAC, FRAP) and antiradical (DPPH) capacities of pumpkin flesh extracts. For the case of Cucurbitaceae, it is a novel approach, first applied in our pilot work [
66], and follows that of the most recent study of Kulczyński et al. [
67]. Similarly to our strategy, these authors have employed several independent methods to evaluate antioxidant potential of 14
C. maxima cultivars. Their optimized extraction method (with 80% methanol/water) was very close to the one elaborated for this study. Here, apart from
C. maxima (out of the eight cultivars, only ‘Hokkaido’ and ‘Buttercup’ were examined in both studies) the testing included also cultivars belonging to other species (
C. pepo,
C. moschata,
C. ficifolia).
The fruit of ‘Hokkaido’ exhibited the maximum antioxidant potential as revealed by the assays CUPRAC, FRAP, and DPPH which are the most sensitive methods towards phenolic compounds [
59]. Positive correlations between TPCs and the antioxidant capacities were also shown in this work (
Table 3). This cultivar is famous for its intensive orange-colored pulp, which results from the high concentration of carotenoids, mainly β-carotene [
33,
34] whose antioxidant activity is based on singlet oxygen quenching and ability to trap peroxyl radicals [
68]. Taking into account the content of phenolic compounds (
Table 2), it is thus justified that both carotenoids and phenolics contributed to the resultant exceptional activity. It should be noted here that in the complementary study [
67] ‘Hokkaido’ also ranked high among the other tested
C. maxima cultivars in terms of antioxidative/antiradical activity. The fruits of ‘Indomatrone’ accumulated the highest amounts of total phenols and, expectedly, they revealed the highest antioxidant capacities as measured by FRAP and CUPRAC assays. At the same time, their antiradical capacity determined upon the DPPH method was the lowest of all the tested fruits. Possibly, the pulp of ‘Indomatrone’ contained some fraction of other polyphenols with a different mechanism of action than the typical polyphenols of
Cucurbita. Note that, in fact, only the DPPH assay allowed for direct measurement of antiradical capacity since DPPH itself is a free radical. Also, high content of soluble sugars as measured for this cultivar should be considered as a reliable explanation of the observed facts. It was demonstrated that the mono- and disaccharides, especially fructose, interfered with the Folin-Ciocalteu reagent, leading to overestimation of the final results [
69]. Hence, the antioxidants of ‘Indomatrone’ fruits require a more detailed analysis.
Many fruits and leaves rich in lutein are considered helpful in treatment of aged-related macular degeneration (AMD) and cataracts as the loss of these pigments in the retina is observed during the AMD development. However, supplementation with sole lutein or with lutein and zeaxanthin had little or no effect on progression of AMD and subsequent AMD vision loss, while additional zinc combined with the antioxidant vitamins (C and E) slowed down progression of this disease [
70].
C. pepo ‘Sweet Dumpling’ and
C. maxima ‘Indomatrone’ were the cultivars with the highestZn content in their fruits (1.23 and 0.88 mg 100 g
−1 f.w., respectively). Note that these levels can cover from 8 to 15% of zinc Recommended Daily Allowance (RDA) for people over 70 years old (
Table S1) [
71,
72]. The two cultivars were also distinguished in the high content of β-carotene (14.6 and 14.8 mg 100 g
−1f.w., respectively) which is a precursor of zeaxanthin. Since the
Cucurbita fruits contain pronounced amounts of vitamin E [
21,
64,
65] as well as these xanthophylls [
64,
65], they seem to have the necessary qualities to slow down the development of the retinal diseases.
Trace elements in human nutrition are required for the proper activity of antioxidant enzymes crucial for efficient defense against the excess of reactive oxygen species (ROS): Cu, Mn, and Zn for superoxide dismutase (SOD), Fe for catalase (CAT), and Se in selenocysteine for glutathione peroxidase (GPx). Our data show that the tested
Cucurbita fruits contained significant amounts of Zn and Cu as referred to RDA values for seniors (
Table S1) [
71,
72]. The highest Cu content was noticed for ‘Kogigu’ of
C. moschata; its 100 g serving allows for 16.5% supply of daily demand for this microelement. It was confirmed that Zn supplementation effectively reduced oxidative stress and generation of inflammatory cytokines such as TNF-α and IL-1β in elderly individuals [
73]. Furthermore, the relationship between Cu to Zn ratio (CZr) and mortality rates gave reasons to suggest that CZr is a biomarker of aging.
The presented research work on fruits of 18
Cucurbita cultivars enabled to compare their antioxidant properties and confirmed the great diversity found for different objects. This observation is similar to that reported by other authors for many other examined cultivars [
64,
65,
67]. Such variability should not be considered surprising, taking into account that pumpkin is one of the first domesticated plants and has been grown worldwide for several hundred years thus giving farmers enough time to obtain and introduce cultivars with unique characteristics. The fruits subjected to our study differed profoundly in terms of the content of phytochemicals as well as their antioxidant potential and antiradical capacity. Statistical analyses show that these differences were associated with distinct characteristics of a particular cultivar, and could not be generalized as specific to individual species. The greatest variations in phenolic content were reported for protocatechuic, syringic, and salicylic acids. Moreover, not all the tested phenols were detected in all the cultivars. Unfortunately, the majority of other available studies on
Cucurbita do not bring results as dependent on examination of several variant cultivars, which leaves little space for making comparisons.
Generally, it is difficult to compare the data on the content of antioxidants in the fruits of different cultivars. The resultant information is influenced by genetic differences and affected by environmental conditions, degree of maturity at harvest, and storage conditions [
74]. Note that
Cucurbita fruits can often be used when they are not yet fully ripe.
C. ficifolia,
C. maxima, and
C. moschata are known as winter squashes that can be stored for months; however, among the
C. pepo cultivars there are several ones whose fruits can be consumed only as summer squashes. Fruit maturation involves a series of complex reactions that lead to changes in plant phytochemistry. Two different phenomena of phenolic compound changes were observed during maturation: a gradual decrease [
75,
76] or an increase at the end of the process [
77,
78,
79]. Furthermore, concentration of antioxidants varied within the plant organs and tissues [
80,
81].
In many research articles, it is stressed that high reactivity and great structural and molecular diversity of phenolics makes them very difficult to study, as evidenced by ambiguous and sometimes contradictory results [
82]. Divergent sample preparation procedures and the lack of measurement standardization are additional reasons for unsatisfactory data comparability. Therefore, we emphasize the need for methodological unification of antioxidant capacity tests based on standardized extraction procedures, especially regarding groups of related plants with similar chemical characteristics. We also point to the fact that extensive studies on beneficial action of phenolic compounds on human health have only started a few years ago [
27]. It is already known that dietary polyphenols undergo several transformations in the body (i.e., deglycosylation, oxidation, dehydroxylation, demethylation), and their bioavailability may vary significantly [
82], usually remaining relatively low [
83]. Therefore, the elevated and potentially toxic concentrations of polyphenols, as reported in several works, can only be reached when these compounds are applied as concentrated supplements or therapeutic medicines [
28]. Unfortunately, the data on the bioavailability of phenolics and other nutrients of
Cucurbita fruits are still scarce. Studies on the content of anti-nutrients such as tannins, oxalates, saponins, phytates, alkaloids, and cyanide in
Cucurbita pulp, demonstrate low or acceptable amounts of these substances as referred to the daily intake [
35,
84,
85,
86]. Considering the above, the application of polyphenols obtained from the natural sources such as cucurbits appear to be the most favorable and the safest way of supplementation.
As regards directions of future studies of natural antioxidative agents, the research should focus on characterizing antioxidant intake mechanisms and correlating them with biological availability. This approach seems to be necessary to complement current efforts made to elucidate the impact of antioxidants on oxidative stress responses. Also it is noteworthy that the antioxidant capacity analyses of this study were performed in vitro and, although the standardized methods were employed, the next-stage complementary research is required involving the in vivo testing with free radicals physiologically present in the human body. Moreover, appropriate clinical trials are necessary to evaluate real dietary potential of pumpkin fruits towards the elderly population.
To conclude, the results obtained from a systematic research on fruits of 18 Cucurbita cultivars bring valuable information on the unique properties of Cucurbita and reveal considerable diversity of both the content of bioactive compounds and antioxidant/antiradical capacities. The detected phenolic compounds, β-carotene, Zn, and Cu could be useful in the nutrition of elderly people suffering from chronic diseases. It is finally emphasized, however, that even if the concentration of a particular nutrient or antioxidant is lower than in other plant material (medicinal plants, herbs, other vegetables), the Cucurbita fruits have the advantage of being easily digestible and possessing low glycemic index, which allows for their supply in high amounts and serving in many variant ways after appropriate processing.