Phenolics content in pasta
Polyphenols are the most common antioxidants in a daily diet. Its’ functional effect is attributed to the anti-inflammatory, antibacterial, antiviral and anticarcinogenic activity in human body as well as high antioxidant capacity, and thus beneficial to the human health. Nicoletti et al. (2015) reported the amount of total polyphenol content in various species of Cistus plant as GEA equivalent and they found 33.16, 32.51 and 40.51 mg GAE/g in C. monspeliensis, C. villosus and C. libanotis, respectively. The amounts of phenolic compounds of dry C. incanus herb methanol extracts (ME) and phosphate buffer saline extracts (PBSE) were found at 301.9 mg GAE/g d.w. and 457 mg GAE/g d.w., respectively. Table 1 shows the content of phenolic compounds in methanol and phosphate buffered saline extracts present in dry pasta. The lowest amount of phenolic compounds (6.64 mg GEA/g d.w.) was found in the ME of wheat pasta without additive. Over twice as more of polyphenols were found in the ME sample supplemented with 5% of C. incanus. The increased amount of phenolic compounds in ME varied from 8.45 mg GEA/g d.w. for pasta with 1% of additive up to 15.27 mg GEA/g d.w. for pasta supplemented with 5% of additive. The content of total phenolic compounds found in PBSE samples showed better extractability of these components from dry pasta than in ME (Table 1). The highest amount of phenolic compounds was identified in pasta with 5% of the C. incanus content, the phenolic compounds content reached 18.28 mg GEA/g d.w. The least amount of phenolic compounds, 8.71 mg GEA/g d.w., was found in ME of pasta sample without additives. The use of dried Cistus plant as an additive in the range up to 5% resulted in an increased phenolics content of about 229.97% if ME was used and 209.87% if PBSE was applied for extraction compared to control sample. The results of phenolic profile and antioxidant capacity of hydromethanolic and aqueous extracts of commercial C. incanus products presented by Viapiana et al. (2017) revealed that aqueous extracts of C. incanus are richer in phenolic compounds and have stronger antioxidant activities than hydromethanolic extracts. Moreover, they found more effective antibacterial activities of aqueous extracts against Gram-positive than Gram-negative bacteria. Pasta products fortified with 1–5% of carob flour showed the increased amount of phenolic compounds from 5.27 mg/g d.w. for pasta with 1% up to 12.12 mg/g d.w. if 5% of carob flour was applied (Sęczyk et al. 2016). Comparying these data with presented results it can be stated that the addition of C. incanus is more beneficial to improve the nutritional quality of wheat pasta than carob flour. Bouasla et al. (2016) reported increased level of total phenolics content in precooked gluten-free rice pasta supplemented with selected legumes: yellow pea, lentil and chick pea, added up to 30%. Chakraborty et al. (2016) noticed that total phenolics content of the pasta and the extruded snacks enriched with a mixture of coriander leaves, curry leaves and fenugreek leaves increased with increrasing the amount of additives. The level of the additives reported in the literature is varying in wide range, but the possibility to apply dried herbs is limited because of its specific intensive aroma and herbal taste. In Table 2 it have been identified significant correlations between phenolics content and antioxidant activity of supplemented pasta. TPC ME was highly positively correlated with the amount of C. incanus (0.98) and with TPC PBSE (0.96), and negatively correlated with the DPPH ME and DPPH PBSE (− 0.91 and − 0.94, respectively). On the other hand, TPC PBSE was highly positively correlated with C. incanus level (0.99) and negatively correlated with DPPH ME and DPPH PBSE (− 0.98 and − 0.96, respectively), with FRAP ME and FRAP PBSE (− 0.91 and − 0.93, respectively) as well as with aroma of dry pasta (− 0.92).
Table 1 The content of polyphenols (mg GAE/g d.w.) in methanol extract (ME) and buffer extract (BE) of dry pasta depend on Cistus incanus participation Table 2 Correlation matrix of selected properties of pasta supplemented with C. incanus Antioxidant activity of pasta tested with DPPH, ABTS and FRAP
DPPH is an example of a long-lived nitrogen radical. Many antioxidants react very slowly on this radical (Gorkem 2016). Determinant of antioxidant activity by DPPH method is the most common method (Boroski et al. 2011). The scavenging capacity of DPPH free radical for C. incanus dry herb was noted at the level of 8.04 mg d.w./mL of EC50 in ME extracts and of 2.6 mg d.w./mL in PBSE extracts. Figure 1 shows the distribution of the activity of compounds contained in ME and PBSE extracts of pasta supplemented with C. incanus leaves. Higher values of these indicators mean lower antioxidant activity. The lowest scavenging capacity of the free radical DPPH was noted in wheat pasta samples with value of 96.54 mg d.w./mL of EC50 in ME extracts. The highest capacity, for both used extractants, was evaluated in extracts of pasta enriched with 5% of Cistus leaves and it was over double more active than in samples without additive. The remaining EC50 values in ME ranged from 41.08 mg d.w./mL (5% of additive) to 87.21 mg d.w./mL (1% of additive). The largest differences in the increase in antioxidant activity have been noted between samples supplemented with 2 and 3% of C. incanus leaves. The ability to scavenge the free DPPH radicals in the tested PBSE, expressed as EC50 index, ranged from 75.00 to 316.22 mg d.w./mL. The scavenging activity of pasta PBSE increased with the addition of dried Cistus leaves amount, the most significant increase of 40% was observed between the samples with 3 and 4% of additive applied. Highly positive correlations (0.98) have been observed between antioxidant activity DPPH ME and DPPH PBSE (Table 2). The antioxidant activity of DPPH ME and PBSE in the same time was highly negatively correlated with the C.incanus amount (both − 0.98) and positively correlated with the FRAP PBSE (0.93 and 0.90, respectively) as well as with aroma of dry pasta (0.94 and 0.92, respectively). Marcinčák et al. (2008) found that the highest antioxidant capacity using the synthetic DPPH radical was characterized by methanol extracts of oregano (95.20%) and lemon balm (91.20%). Moreover, Chakraborty et al. (2016) reported that pasta enriched with a mix of leaves (coriander, curry, fenugreek) characterized greater ability to scavenge free radicals than extruded snacks, so supplementation of cold-pressed pasta could be an efficient way to improve nutritional quality according to the antioxidant activity of final products. But it was also found a small effect of HTST extrusion-cooking treatment on antioxidant activity of extrudates supplemented with chamomile, echinacea or elderberry fruits or flowers (Oniszczuk et al. 2015b, c, 2016a, b, respectively).
The results of the antiradical activity of free radicals against ABTS of compounds contained in ME and PBSE extracts, shown in Fig. 1, confirmed previous tendencies observed for DPPH. The antiradical activity of C. incanus dry herb against ABTS was characterized in ME and PBES extracts with the EC50 at 14.2 and 10.8 mg d.w./mL, respectively. The lowest antiradical activity was characterized by extracts of wheat pasta made without the addition of a plant with a EC50 at 214.73 and 59.65 mg d.w./mL in methanol and buffer extracts, respectively. Enrichment of pasta with 1% addition of dried Cistus leaves resulted in a 62% increase in activity against ABTS in ME and 32% in PBSE. The antiradical activity increased by over 87% in ME and 52% in PBSE when tested material contained 5% of additive. The Table 2 shows that between antioxidant activity of ABTS ME and ABTS PBSE was observed highly positive correlation (0.98). The antioxidant activity of ABTS ME and PBSE were highly positively correlated with the FRAP ME (0.98 and 0.99, respectively) and FRAP PBSE (0.93 and 0.96, respectively). However, the only antioxidant activity of ABTS PBSE was highly negatively correlated with the cooking weight index (− 0.91). The results obtained by Sant’Anna et al. (2014) suggest that the scavenging capability of the ABTS free radicals of pasta supplemented with grape marc powder is related to the presence of anthocyanins in the final product. While Sęczyk et al. (2016) observed that for wheat pasta fortified with carob flour (1–5%) inreased antiradical activity from about twofolds to 18-folds.
The results of ferric-reducing power of ME and PBSE of tested pasta are presented in Fig. 1. The increase in reduction capacity against FRAP was related to the increasing amount of C. incanus in the composition (Table 2). ME of wheat pasta characterized the reduced capacity against FRAP expressed as EC50 (71.80 mg d.w./mL). For ME and PBSE extracts of dry C. incanus herb the reduction capacity of FRAP was noted at 0.62 mg d.w./mL and 0.42 mg d.w./mL, respecively. The best ability to reduce ferric ions by the compounds contained in the ME of enriched pasta was found in samples with a 5% of plant leaves, it has reached the EC50 value of 14.32 mg d.w./mL. According Biernacka et al. (2017) the ferric-reducing power is increasing with increased amount of carob fiber in the wheat pasta. The FRAP abilities to reduce the compounds contained in the PBSE of the tested pasta were found in a range of EC50 from 72.95 mg d.w./mL to wheat pasta up to 25.65 mg d.w./mL for pasta with 5% of additive. So, the increase in ferric-reducing power was significant (20% in ME and 35% in PBES). However, not dependently the extraction procedure, the highest reducing capacity was observed in the pasta with the largest amount of C. incanus in the recipe. Nicoletti et al. (2015) reported the results of antioxidant activity against DPPH for extracts from various species of Cistus plant. They found significant differences between various types of tested plants, both as DPPH antiradical activity as well as reducing power EC50, in a range of 3–28 µg/mL and 142–28 µg/mL, respectively. Loizzo et al. (2013) tested antioxidant properties as radical scavenging ability and ferric reducing ability of five species of Cistus essential oils with DPPH, ABTS and FRAP tests, respectively. They found DPPH antiradical activity ranged from 499.9 to 991.9 µg/mL, ABTS ranged from 272.5 to 395.1 µg/mL and FRAP ability ranged from 0.4 to 19.4 µM Fe/g. Highly positive correlations were observed between reduction capacity against FRAP of ME and PBSE extracts and antioxidant activity measured with other methods (Table 2). Additionally, highly negative correlations were noted between the additive amount and reduction capacity against FRAP ME and PBSE (− 0.90 and − 0.94, respectively). Significant correlations have been found also with color determinants of cooked pasta as well as with sensory properties of dry products. Wheat pasta fortified with carob flour by supplementation of 1–5% had an effect on increased ability to reduce Fe3+ ions from about 100–300% (Sęczyk et al. 2016). Cárdenas-Hernández et al. (2016) noted that pasta exhibited higher phenols content than pure pasta and reduced antioxidant power once enriched with amaranth addition, especially the leaves.
Cooking quality of pasta
Results of cooking quality of pasta enriched with C. incanus dried leaves are presented in Table 3. The optimum cooking time (OCT) evaluated for wheat pasta and products enriched with C. incanus dried leaves was 12.5 min and differences between tested samples were not significantly different (± 0.5 min), probably due to the small amount of additive used in the experiment. The cooking weight index (CWI) was found on the level of 3.28 for the wheat pasta without additive. Application of C. incanus dried leaves as an additive influenced variously on the cooking weight of supplemented pasta. Obtained values ranged from 3.20 when tested pasta with 1% of C. incanus addition to 3.36 for pasta supplemented with 3% of dried leaves added. Higher amount of additive lowered CWI because of disruption of continuous gluten matrix by the addition of herbal component with high fiber level. Nevertheless, observed differences in CWI were not significantly different. In the case of wheat pasta, fortification with carrot and oregano leaves also had no significant effect on the technological quality of the final product (Boroski et al. 2011). Cooking weight is more dependent on the preparation time as reported by Dziki and Laskowski (2005) during evaluation of spaghetti-type pasta produced from semolina, they observed the cooking weight index increased significantly from 2.7 for OCT to 3.3 during overcooking. Biernacka et al. (2018) reported the weight increase index of pasta from 2.62 to 3.00 if various wheat pasta were tested, whereas the cooking loss varied from 4.76 to 6.55%. They found significant and negative correlation was found between protein content and CL. In our study cooking loss of pasta supplemented with C. incanus not exceed 10% what is indicating pasta with high quality. Significant positive correlation of CWI was observed with hardness of cooked pasta (0.72, Table 2). Moreover, CL was significantly positively correlated with optimum cookin time and with taste of cooked pasta (0.69 and 0.63, respectively). As shown in Table 3 increased amount of additive in the recipe resulted in higher cooking losses from 5.7% for control wheat pasta up to 9.8% for products supplemented with 5% of Cistus herb. Addition of dry herbs lowered the total amount of proteins and disturbed the continuous gluten matrix by the addition of high-fiber dry plant fractions. It is well known that lower protein content results in a weaker protein matrix and higher CL so by increased addition of Cistus leaves the total protein content decreased (Biernacka et al. 2018). Boroski et al. (2011) found the highest soluble losses during cooking for pasta supplemented with 20% of oregano and carrot leaf meal what may be related to structural changes in the gluten chain caused by proteins in the leaf meal.
Table 3 Results of cooking characteristics and texture of dry and cooked wheat pasta depend on Cistus incanus participation Hardness of pasta was tested for dry and cooked products. Pasta cutting force as an indirect indicator of pasta hardness is a frequently determined for single or multiple pasta treads (Bouasla et al. 2016; Gull et al. 2015). Dry pasta hardness, expressed as cutting force, did not differ significantly, except of sample with the highest amount of C. incanus dry leaves what showed low cutting force (Table 3) as the result of weak inside structure of dry pasta and tendency to crush very easily. Hardness of cooked pasta ranged from 0.26 N for control wheat pasta up to 0.41 N for samples with 5% of dry Cistus added. High content of fiber in pasta recipe caused higher hardness after OTC. This could be the result of the competition for the water molecules between starch, proteins and fiber and different hydration levels of the constituents, which in turn can affect the strength of gluten network formed (La Gatta et al. 2017). Biernacka et al. (2018) found cooked pasta hardness ranged from 0.52 to 1.65 N for various types of commercial wheat pasta products based on common and durum wheat flour. Table 2 shows that hardness of cooked pasta was significantly negatively correlated with only sensory color of dry pasta (− 0.66).
Color determination of pasta products
According to Italians, who are the leaders in Europe in the consumption of pasta, good quality pasta should have the yellow color which is desirable by consumers (Piwińska et al. 2016). Moreover, color of the product is the first evaluated parameter affecting on buying decisions. In the case of tested pasta fortified with C. incanus evaluation of color discriminants for dry and cooked pasta occurred with the coordinate system L*, a* and b* (Table 4). The highest brightness (value L* = 74.58) was observed for dry pasta without additives. For dry pasta the lowest value of this parameter 61.06 was noted for products fortified with 5% of C. incanus in the composition. There was observed significant differences between samples, especially comparing to control sample. Addition of 1–3% of dried Cistus leaves did not affected significantly on dry pasta brightness. While determining the brightness of cooked pasta the highest value of the L* coordinate was noted in wheat pasta without the addition of C. incanus with the value of 52.22. In relation to pasta before cooking the decrease in brightness occurred by approx. 30%. The lowest value of L* coordinate for cooked pasta was determined for pasta with 5% addition of dried Cistus leaves (40.02). Increasing the amount of Cistus additive caused significant reduction of cooked pasta brightness because of the brown–red shade of dry herb. There was also observed significant decrease in supplemented products brightness after cooking compared to dry pasta. The decrease in brightness of pasta could be the result of non-enzymatic browning, Maillard reactions occurred at very high temperature of drying or additives applied (Piwińska et al. 2016). Significant positive correlations (Table 2) were observed between value L* of dry pasta and value L* of cooked pasta (0.64). Furthermore, value L* of dry pasta was significantly negatively correlated with a* and b* value of dry pasta (− 0.72 and − 0.67, respectively). Also, the L* value of cooked pasta was significantly negatively correlated with additive amount, total phenolic content and b* of dry pasta whereas the positive correlations have been found between lightness of cooked pasta and its antioxidant activity (Table 2). Quite opposite tendencies were observed for b* of cooked pasta. The chromatic coordinate a*, indicating redness-greenness balance reached in-plus values what is associated with the slight brown–red tint of dry pasta. The highest a* value was determined for dry and cooked pasta with addition of 1% of C. incanus and was respectively 3.33 and 4.38 (Table 4). In dry pasta a small increase of redness intensity was observed according to increased level of dry Cistus leaves because of its brown–red shade after drying. Not significant differences were observed in a* coordinate values for cooked pasta, slide increase in redness was noted for samples with increased dried herb addition. Small differences in pasta redness before and after cooking showed similar red tint of both dry and cooked pasta. According to Biernacka et al. (2017) the effect of the color characteristic depends on the raw materials, processing parameters and especially drying conditions. The authors observed that addition of carob fiber to common wheat pasta decreased the value of the a* coordinate from 17.3 to 2.7. Uncooked pasta with spinach showed intensive green color as seen by negative a* value that indicates green shade opposite to carrot, beetroot and tomato supplemented pasta (Rekha et al. 2013). They reported the color of cooked samples was slightly lesser as compared to dry ones and leaching of color components during pasta cooking was negligible probably due to solubility in water carotenes and chlorophylls from vegetables. Significant positive correlation (0.63) was observed between value a* and b* of dry pasta. Color coordinate a* was positively correlated with additive amount and TPC whearas negative correlations have been found with antioxidant activity, especially by DPPH and FRAP radicals scavenging power (Table 5).
Table 4 Mean values of color coordinates L*, a* and b* of pasta depend on Cistus incanus participation Table 5 Results of acceptability of dry and cooked wheat pasta supplemented with addition of dried Cistus incanus leaves During the assessment of the b* coordinate (Table 4), the highest intensity of the yellow shade was determined for dry pasta with 5% C. incanus content (17.66), while the smallest value, 10.52, was determined during testing wheat pasta without the addition of C. incanus. For cooked pasta, the b* coordinate value assumed a maximum value of 14.95 during evaluating the color of the pasta with a 5% C. incanus, while the lowest intensity of yellowness 6.66 was characterized by wheat pasta as control sample. The increase in b* values for dry pasta was 67% according to color of control sample, while after cooking increase in yellowness was more significant (124%). Difference in yellowness between dry and cooked products was about 16–20% for pasta with the same content of C. incanus, but for control pasta difference was more visible (37%). Reduction in yellow color intensity of cooked pasta could be due to swelling of pasta and conversion of pigments resulting in decrease in yellowness during cooking, but all the tested pastas had good attractive color after cooking. b* value of dry pasta was positively correlated with amount of additive, TPC, a* and value b* of cooked pasta but negatively correlated with antioxidant activity for all the tested extracts, with L* of cooked pasta as well as with sensory characteristics of dry products (Table 2).
Sensory evaluation of pasta
During the sensory evaluation of dry pasta (Table 5) the highest scores of the overall acceptability were noted for the control pasta and samples enriched with 1 and 2% of C. incanus added. With the increase of the amount of herbaceous additive, lower notes were observed for the color assessment, because of higher additive level visually resulted in the loss of the color uniformity. The increasing amount of the additive in the evaluation of raw pasta resulted in lowering the ratings for the external appearance. Most likely, this was due to the appearance of dark spots that resulted from the addition of C. incanus. The increase of C. incanus addition in pasta recipe also adversely affected the assessment of the aroma because of too intensive herbal flavor resulted in lowering the scores for the aroma of pasta with an additive content above 3%. The overall quality counted as mean of all assessed features showed that the control pasta and products with 1 and 2% of the additive content received the score 7.5, which constituted of 83.3% of the possible points. Pasta with 3% C. incanus received approximately about 30% less points than the top ones. The pasta with the addition of 5% of the herb supplement was rated the worst, receiving 4.3 points, which constituted 47.7% of total points to be awarded. Table 2 shows that appearance, color and aroma of dry pasta as well as appearance of cooked pasta were negatively correlated with additive amount. Assessment of cooked pasta sensory attributes showed the highest overall acceptability was found for pasta supplemented with 1% of C. incanus dry leaves. The pasta made with this recipe after cooking characterized the best appearance, color, taste and texture. When assessing the aroma, as compared to pasta with 1% of the additive, slightly higher scores were noted for pasta with 4% of C. incanus content. The lowest rated product was cooked pasta with 5% content of additive, the lowest scores for all sensory attributes were noted for this product. Significant positive correlation (0.65) was observed between the taste and texture of cooked pasta (Table 2). Whereas, as reported by La Gatta et al. (2017), supplementation of pasta with high-fiber bran fractions may cause a weakening of the gluten protein network and may have a detrimental effect on its cooking and sensory quality. So the level of fibrous additives for pasta supplementation must combine nutritional properties, proper cooking quality and sensory attractiveness. Supplementation of the health ingredients should have no effect on the palatability as well as the consumer preference. Apart from the additional health benefits it offers, it should be rather delicious as well (Krishnan and Prabhasankar 2012). Taking all these into account it can be stated that pasta with maximum level of 3% of C. incanus addition is still acceptable as well as presents improved nutritional characteristics.