Introduction

The agri-food sector generates a substantial amount of waste, including crop residues like stalks, leaves, and husks, as well as by-products from food processing, ranging from peels and shells to stems, expired or unsold food, and packaging materials. Effectively managing and reducing this waste is crucial for promoting environmental sustainability, enhancing resource efficiency, and preventing food loss and waste1,2.

Implementing proper waste management practices plays a vital role in minimizing the sector’s environmental impact. Strategies such as recycling, composting, and optimizing packaging can significantly reduce waste generation3. Recycling and reusing packaging materials not only conserve resources but also reduce the volume of waste that ends up in landfills. Composting organic waste, such as crop residues and food processing by-products, helps produce nutrient-rich soil amendments and reduces reliance on synthetic fertilizers4,5,6.

Preventing food loss and waste is a fundamental aspect of building a more sustainable food system. By reducing food waste at various stages of the supply chain, valuable resources like water, energy, and land can be conserved, while also minimizing associated greenhouse gas emissions7.

Onion (Allium cepa L.) is an example of a widely consumed vegetable that contributes considerably to municipal and industrial wastes, consisting of onion skins, outer fleshy scales, roots, leaves and the apical and basal trimming of bulbs and are commonly known as onion solid wastes (OSW)8,9.

An enormous amount of OSW is generated in several countries. For example, in California, USA, approximately 100,000 tons of OSW are produced annually. Similarly, in the European Union, particularly in Spain, Holland, and the UK, about 500,000 tons of OSW are generated each year10. Despite being considered waste products, OSW are of great interest for the recovery of active ingredients. Several studies have contributed to the development and validation of extractive techniques designed for the isolation and purification of bioactive compounds from onion bulb11,12, skin13,14,15,16, peel17,18 and solid wastes19,20. However, despite their significant nutraceutical potential, research focused on onion leaves has remained limited. Fresh onion leaves contain high levels of bioactive compounds such as polyphenols, flavonoids, carotenoids, vitamins, and chlorophylls21,22. This study aimed to investigate, for the first time, the antioxidant properties of green onion stalks sourced from the “Cipollotto Nocerino” onion (CN) variety. These leaves are characterized by intensely green colour, linear in shape, and end in a pointed tip. They constitute the primary by-product of CN, measuring approximately 15–30 cm in length, a size six to seven times larger than that of its bulb.The CN is a type of onion bulb that has been cultivated for over 2000 years in Campania region, especially in the areas of Pompeii-Nocera. It is characterized by several distinctive features. The harvested bulbs measure 2–4 cm, which classifies them as medium-small-sized onions. The bulb has a cylindrical shape and is flattened at the poles, with a slight thickening at the base of the leaves. The inner and outer layers of the bulb are completely white, and the flesh is succulent and sweet in taste. As a spring harvest onion (from March to June), it is primarily consumed fresh and does not have a high capacity for storage. The annual production is approximately 50,000 tons of fresh produce, resulting in a turnover exceeding 30 million euros. The CN has been granted the Protected Designation of Origin (PDO) status (Reg. CE n. 656/2008)23. Several studies have investigated the extraction of bioactive compounds from onion leaves, mainly using the conventional extraction technique24,25,26. These methods typically involve macerating the leaves in different solvents (e.g., ethanol, ethanol/water, or acetone) at varying times and temperatures to optimize the extraction process. This method takes a lot of time, energy, and solvent during processing27,28,29,30.

Recently, optimal conditions for ultrasound-assisted extraction (UAE) have been identified to obtain extracts from Welsh onion leaves. These extracts exhibit high polyphenol content and 2,2-Diphenyl-1-picrylhydrazyl (DPPH) scavenging activity31. UAE technique has gained popularity due to its ability to reduce solvent consumption, shorten extraction time, and improve extraction yields. UAE operates through the mechanical and cavitation effects generated by ultrasonic waves, which enhance the mass transfer of targeted compounds by breaking down the cell walls of the plant material32,33. However, ultrasonication system has disadvantages such as being expensive, occurring undesirable changes in molecules and requiring optimization. Another environmentally friendly extraction technique is microwave-assisted extraction (MAE), which involves the irradiation of samples soaked in a solvent. In contrast to conventional extraction methods, microwave irradiation can directly heat the reactants and solvent by passing through the walls of the reaction container. MAE is widely used in laboratories due to its numerous advantages. It helps reduce energy consumption and the amount of organic solvents required, leading to a decrease in waste generation. Its ability to efficiently extract bioactive compounds makes it a valuable tool in the field of natural product extraction and has gained considerable attention in scientific research and industrial applications34,35.

However, the complexity of mass transfer and the limited depth of microwave irradiation, influenced by factors including temperature and microwave frequency, present challenges for upscaling the MAE process. Therefore, achieving scale-up of MAE for industrial applications requires an in-depth analysis of how various parameters affect extraction kinetics. Consequently, it is crucial to develop models that can predict the optimum MAE conditions36,37,38.

In this current study, we assessed the phytochemical composition and antioxidant properties of CN leaves, aiming to unlock the potential value of this by-product (leaves) for nutraceutical, nutritional, and pharmacological uses. For these purposes, we developed and optimized an alternative method based on MAE for the recovery and isolation of bioactive compounds from CN leaves. A response surface methodology (RSM) through a Box–Behnken design (BBD) was applied, and model fit, regression equations, analysis of variance and 3D response curves were developed. Temperature (60–100 °C), time (5–25 min), extraction volume (6–12 mL) and ethanol concentration (40–80% v/v) were studied as the major parameters affecting the extraction efficiency and the antioxidant properties. A Box–Behnken design was adopted considering total phenolic content (TPC) and ferric reducing antioxidant power (FRAP) as responses. A Liquid Chromatography-High-Resolution Mass Spectrometry (LC-HRMS) platform was employed to elucidate the polyphenol profile of CN extract, which was obtained under the optimal extraction conditions determined by developed model. Additionally, in vitro evaluation of cell safety and the quenching of H2O2-induced intracellular reactive oxygen species (ROS) exerted by optimal CN extract were evaluated in a hepatocarcinoma cell line.

Materials and methods

Materials

Folin Ciocalteu’s reagent, gallic acid, sodium carbonate, 2,4,6-Trippyridyl-s-triazine (TPTZ), sodium acetate, acetic acid glacial, hydrochloric acid 37%, Iron(III) chloride hexahydrate, Iron(II) sulfate heptahydrate, 3-[4,5-dimethylthiazol-2,5-diphenyl-2H-tetrazolium bromide (MTT), 6-carboxy-2ʹ,7ʹ-dichlorodihydrofluorescein diacetate (DCFH-DA), hydrogen peroxide were obtained from Merck Life Science, Milan, Italy. All the solvents and additives LCMS grade were purchased from VWR Chemicals, Milan, Italy. CNs were kindly donated by consortium for the protection of “Cipollotto (spring onions) Nocerino DOP”.

Methods

Sample preparation

Green onion stalks (leaves) were selected for the extraction of antioxidant compounds. The onion leaves used in this study are not from endangered species. The principles of experimental research and field studies on plants, including the collection of plant material, were conducted in accordance with relevant institutional, national, and international guidelines and legislation for plant material research. Subsequently, the collected samples were labelled, stored in a cooler and transported to the laboratory. The leaves were lyophilized for 24 h (Manifold Freeze Dryer MFDQ 2002, Laboquest, Westchester USA), using condenser temperature at − 80 °C and 1 Pa as vacuum pressure. After lyophilization, the dried leaves were milled into a powder and stored at − 20 °C until further analysis. Microwave-based extraction experiments were performed in a PreeKem-M3 digestion system equipped with an HP10 rotor (Preekem Scientific Instruments Co., Shanghai, China). The microwave frequency was set at 2450 MHz while the microwave power (watt) was automatically adjusted by the instrument’s program based on thermal conditions, time, and the number of vessels. Notably, it was determined that 100, 250 and, 500 W correspond to 60, 80 and, 100 °C, respectively. After MAE, CN extracts were centrifuged at 6000 rpm for 10 min at 4 °C (Mikro 220R centrifuge, Hettich, Germany) and the supernatants were frozen overnight at − 20 °C to facilitate the precipitation of interfering compounds. Finally, the extracts were freeze-dried, reconstituted with 1 mL of the corresponding extracting solvent, and subjected to spectrophotometric analysis.

The extraction yield for each run and for the optimal extract was calculated according to the following equation:

$$\text{Extraction yield (\%) } = \frac{\text{W}1}{\text{W}0}\times 100,$$
(1)

where W1 and W0 are the weights of the final dry extract and the initial sample, respectively.

Extraction yield data were reported in the supplementary information (Table S1).

Optimization of extraction variables using Box–Behnken design and method validity testing

The relationship between four independent variables (A: temperature, 60–80–100 °C; B: time, 5–15–25 min; C: extraction volume, 6–9–12 mL; D: ethanol concentration, 40–60–80% v/v) and the dependent variables (responses) of total phenolic content (TPC, Y1) and reducing power (FRAP assay, Y2) was assessed using BBD-RSM modeling Each independent factor was associated with three distinct coded levels (− 1, 0, 1) (Table 1).

Table 1 Extraction variables selected for BBD optimization.
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A total of 29 experimental runs, comprising five central points, were generated. All experiments were performed randomly, and the range of the studied variables was selected according to preliminary tests and experimental limitations. All analyses were performed in triplicate (to calculate the reproducibility of the process) and the results were expressed as mean ± standard deviation (SD). RSM was performed using the Design Expert 11 software (Stat-Ease, Inc., Minneapolis, MN, USA) and the experimental data were subjected to regression analysis based on Eq. (2) to obtain quadratic polynomial empirical models:

$$Y = {\beta }_{0}+ \sum {\beta }_{i}{X}_{i}+ \sum {\beta }_{ii}{{X}_{i}}^{2}+ \sum \sum {\beta }_{ij}{X}_{i}{X}_{j},$$
(2)

where Y is the predicted response, Xi and Xj are independent variables, β0 is the intercept coefficient, βi is the linear coefficient, βii is the quadratic coefficient, and βij is the interaction coefficient of i and j variables.

The response surface and contour plot approaches were used to visualize the correlation between responses and different levels of independent variables and interaction types between two independent variables.

A final confirmation experiment (n = 3) was performed using optimized independent extraction variables, and the experimental data were compared with predicted values for model validation.

The analysis of variance (ANOVA) method was employed, and the maximum R2 and adjusted R2 values were used to assess the accuracy of the estimated coefficients. A confidence level of 95% was adopted to determine the significance differences and p-values ≤ 0.05 considered to be significant.

Total phenolic content analysis

The TPC of CN extract was determined using the Folin–Ciocalteau method as described by Way et al., with slight modifications39. Reagent A was prepared by combining 5 mL of 2 M Folin–Ciocalteu reagent to 45 mL of distilled water. For reagent B, 2.87 g of sodium carbonate was dissolved in distilled water in a 25 mL volumetric flask. For each sample, 2 μL of extract was added to 100 μL of reagent A in a microplate, mixed, and left for 5 min before adding 70 μL of reagent B and mixing. Then, the microplate was incubated for 1 h at 40 °C. The absorbance of the solution was then evaluated at 765 nm using a Multiskan SkyHigh Microplate Spectrophotometer (Thermo Fisher Scientific, Waltham, MA, USA). Gallic acid was selected as the standard. Stock solution (1 mg/mL) was prepared in MeOH, and the calibration curve was obtained in a concentration range of 10–200 mg/L, with five concentration levels (y = 991,17683x − 0.08039) and the linearity of the standard curve was 99.99%. The solution was measured in triplicate. The total phenolic content was calculated and expressed as milligrams of gallic acid equivalents per gram of dry weight (mg GAE g−1 dw).

Ferric reducing antioxidant power assay

The FRAP method is based on the reduction of ferric ion (Fe3+) to ferrous ion (Fe2+). The assay was conducted with slight modifications to the conditions previously described by Noreen et al.40. FRAP reagent was prepared by mixing three solutions: A, 300 mM sodium acetate buffer, pH 3.6; solution B, 10 mM TPTZ solution in 40 mM HCl; and solution C, 20 mM ferric chloride (FeCl3) in a volumetric ratio of 10:1:1 v/v/v, respectively. The reagent was kept in darkness for 30 min to complete the reaction. Briefly, 5 μL of CN extracts were mixed with 145 μL of FRAP reagent. FeSO4 was used as analytical standard (0.1–5 mM; y = 2.71450x + 0.01491; R2 = 99.99%). All the samples were prepared in triplicate, shaked and incubated in dark for 30 min at 37 °C. Changes in the absorbance of the samples were measured against blank at 593 nm using a microplate reader. FRAP activity was calculated as millimoles of ferrous equivalent per gram of dry weight (mmol Fe(II)E g−1 dw).

UHPLC-HRMS/MS conditions

UHPLC-HRMS/MS analysis was performed on a Thermo Ultimate RS 3000 coupled online to a Q-Exactive hybrid quadrupole Orbitrap mass spectrometer (Thermo Fisher Scientific, Bremen, Germany) equipped with a heated electrospray ionization probe (HESI II).

The separation was performed in reversed phase mode, with a Kinetex® 2.6 µm EVO C18 100 Å, 150 × 2.1 mm analytical column (Phenomenex, Bologna, Italy) thermostated at 40 °C. The mobile phases were H2O (A) and ACN (B) both acidified with 0.1 v/v % HCOOH delivered at a constant flow of 0.4 mL/min. The following gradient was employed: 0.01–25.00 min, 2–30% B; 25.01–35.00 min, 30–100% B; 35.01–37.00 min, isocratic to 100% B; 37.01–39.00 min, 2% B; then 5 min for column re-equilibration. 2 µL of CN extract were injected.

The ESI was operated both in negative and positive mode. The MS was calibrated by Thermo calmix Pierce™ calibration solutions in both polarities. Full MS (100–1500 m/z) and data-dependent MS/MS were performed at a resolution of 35,000 and 17,500 FWHM respectively, normalized collision energy (NCE) values of 15, 20, and 25 were used. Source parameters: Sheath gas pressure, 50 arbitrary units; auxiliary gas flow, 13 arbitrary units; spray voltage, + 3.5 kV, − 2.8 kV; capillary temperature, 310 °C; auxiliary gas heater temperature, 300 °C.

The identification of analyzed compounds was carried out by comparing their retention times and MS/MS data with those present in the literature. Data analysis and processing were performed using FreeStyle™ 1.8 SP2 and the commercial software Compound Discoverer v. 3.3.1.111 SP1 (Thermo Fisher Scientific, Bremen, Germany). The following online databases were also consulted: Phenol-Explorer (www.phenolexplorer.eu), PubChem (https://pubchem.ncbi.nlm.nih.gov), FooDB (https://foodb.ca/) and, ChemSpider (http://www.chemspider.com).

Cell culture and drug treatment

The human hepatocarcinoma Hep G2 cell line was obtained from GMIST cell bank (Genova, Italy). Cells were grown in Eagle’s minimum essential medium, supplemented with 10% (v/v) fetal bovine serum (FBS), 1% (v/v) nonessential amino acid, 2 mM l-glutamine, 100 U/mL penicillin, and 100 mg/mL streptomycin.

Cells were routinely grown in culture dishes (Corning, Corning, NY) in a humidified atmosphere of 5% CO2/95% air at 37 °C and splitted every 2 days. The viability was monitored using phase contrast microscopy and trypan blue staining. In each experiment, cells were placed in a fresh medium and cultured in the presence of the optimal CN extract at different concentrations and times. Each treatment and analysis were performed in triplicate separate experiments. Cells were used at the 16–20th passage.

Cell viability assay

Cell viability was established by measuring mitochondrial metabolic activity with MTT. Briefly, Hep G2 (30 × 103 cells/well) were plated into 96-well plates, then CN extract (1.56–200 µg/mL) was added for 24 h. Afterward, MTT reagent (0.5 mg/mL) for 2 h was added. Then, 100 μL per well of 0.1 M isopropanol/HCl solution was added to dissolve formazan. The absorbance was measured at 570 nm, using a microplate reader (Multiskan Go, Thermo Scientific, Waltham, MA, USA). Cell viability was expressed as a percentage relative to the untreated cells cultured in medium with 0.1% DMSO and set to 100%, whereas 10% DMSO was used as positive control and set to 0% of viability. The EC50 values were calculated using GraphPad Prism 8.0 software by nonlinear regression of the dose–response inhibition.

Statistical analysis

Data are reported as mean ± SD of results from three independent experiments. Statistical analysis was performed using ANOVA test, and multiple comparisons were made with the Bonferroni’s test with GraphPad Prism 8.0 software (San Diego, CA, USA). Significance was assumed at p < 0.05.

ROS detection

ROS levels were measured as previously described41. To test the effect of CN extract (50, 25 µg/mL) to ROS neutralization, Hep G2 cells were seeded (30 × 103 cells/well) in black 96-well ViewPlate (PerkinElmer, USA) allowing to adhere for 24 h. Next, cells were incubated with both CN extract and H2O2 (800 μM) for 1 h. H2O2 alone (800 μM, 1 h) was used as positive control.

After treatments, the medium was removed, and the cells were washed with PBS. A staining solution containing 10 μM DCFH-DA in serum-free medium without phenol-red was added for 30 min at 37 °C in the dark. The fluorescence signals (excitation/emission 485 nm/535 nm) were read in end point mode using a PerkinElmer EnSpire multimode plate reader.

Statistical analysis

Data are reported as mean ± SD of results from three independent experiments. Statistical analysis was performed using ANOVA test, and multiple comparisons were made with the Bonferroni’s test with GraphPad Prism 8.0 software (San Diego, CA, USA). Significance was assumed at p < 0.05.

Result and discussion

In this study, we examined the health benefits of onion wastes, specifically focusing on the leaves of a spring onion variety called “Cipollotto Nocerino” from the Campania Region. Our main objective was to investigate its potential as a source of antioxidant compounds.

MAE conditions for isolating antioxidant compounds were optimized using a BBD with a total of 29 runs. The study considered the influence of four independent variables: temperature, extraction time, ethanol concentration, and solvent volume. Table 2 shows the comprehensive experimental design, including the predicted and experimental values of TPC and FRAP.

Table 2 Experimental conditions for BBD the corresponding experimental and predicted values of TPC and FRAP.
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The TPC values range from 0.76 to 1.43 mg GAE g−1 dw, while the FRAP values range from 8.25 to 14.80 mmol Fe(II)E g−1 dw.

The experiments corresponding to five central points (runs: 13, 14, 15, 16, and 17) resulted in mean values of 1.09 ± 0.02 mg GAE g−1 dw (RSD = 1.91%), and 11.61 ± 0.32 mmol Fe(II)E g−1 dw (RSD = 2.76%) for TPC and FRAP, respectively, providing acceptable RSD values and an adequate agreement with the model.

According to the multiple regression analysis, the following quadratic polynomial empirical Eqs. (3) and (4), describing the relation between each response variable and the independent variables, were obtained; where A, B, C, and D correspond to temperature, extraction time, solvent volume, and ethanol, respectively.

$$ TPC = { 1}.0{87}0{1 } + - - 0.0{5998 } \times {\text{ A }} + \, 0.0{515779 } \times {\text{ B }} + \, 0.{159185 } \times {\text{ C }} + \, 0.0{5}0{3527 } \times {\text{ D }} + - - 0.0{561667 } \times {\text{ AB}} + \, 0.0{82}0{612 } \times {\text{ AD }} + - - 0.0{53}000{4 } \times {\text{ BC}} + \, 0.0{962268 } \times {\text{ CD}} + \, 0.{135}0{82 } \times {\text{ B}}^{{2}} + - - 0.0{3266}0{7 } \times {\text{ C}}^{{2}} + - - 0.0{841261 } \times {\text{ D}}^{{2}} , $$
(3)
$$ FRAP = { 11}.{6}0{53 } + - - 0.{511671 } \times {\text{ A }} + \, 0.{28}0{19 } \times {\text{ B }} + { 1}.{9}0{122 } \times {\text{ C}} + \, 0.{629}0{48 } \times {\text{ AD }} + \, + \, 0.{658719 } \times {\text{ B}}^{{2}} + - - 0.{924372 } \times {\text{ D}}^{{2}} . $$
(4)

Influence of operational parameters on total phenolic content and ferric reducing antioxidant power

Table 3 shows the ANOVA results for RSM models used to analyse the TPC and FRAP responses.

Table 3 Analysis of variance for the independent variables Y1 (TPC) and Y2 (FRAP) studied in the extraction of CN by the experimental treatments.
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The F-values of 43.49 (TPC) and 28.33 (FRAP) and p-values less than 0.05 indicate model terms are significant. The quadratic coefficients B2, C2 and D2 as well as the interaction coefficient AB, AD, BC, CD were significant in the model developed for total phenolic content (p < 0.05) while that factors A, B, C, AD, B2 and D2 had significant effects (p < 0.05) on the reducing power.

In addition, the high R2 (0.98, and 0.97 for TPC, and FRAP, respectively) and Adj-R2 values (TPC: 0.96; FRAP: 0.93), the coefficient of variation CV (TPC: 3.10; FRAP: 3.43) and the non-significant values for lack of fit (p > 0.05, TPC: 0.13; FRAP: 0.33) confirmed that the mathematical model of equations was able to predict the total phenolic content and antioxidant properties according to the various combination of variables values.

Additionally, the accuracy of the regression model was assessed by evaluating the Diagnostic plot of predicted vs. actual values. The comparison between the predicted and actual response, as showed in Fig. 1, confirms that the experimental values align closely with the predicted values, indicating a good fit without any significant deviations.

Figure 1
figure 1

Diagnostic plot obtained by the BBD of predicted values versus actual values for TPC (left) and FRAP (right).

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The response surface plots showed the impact of different process variables on TPC (Fig. 2) and FRAP (Fig. 3) values.

Figure 2
figure 2

Three-dimensional surface plots were utilized to illustrate the interactions among various process variables on TPC: (a) temperature vs time; (b) temperature vs EtOH concentration; (c) extraction volume vs time; (d) EtOH concentration vs extraction volume.

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Figure 3
figure 3

Response surface plots showing significant interactions between independent variables on FRAP: (a) temperature vs EtOH concentration; (b) temperature vs extraction volume; (c) temperature vs time; (d) extraction volume vs time.

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A significant positive interaction was observed between time and extraction volume (Figs. 2c, 3d), enhancing TPC and antioxidant activity. It is well-known that an increase in time and extraction volume can enhance the solubility of polyphenolic compounds from vegetable matrices, facilitating their diffusion into the extraction solvent42.

These findings are in line with previous studies, wherein it was demonstrated that high amount of solvent increases its penetration through the cell wall by causing swelling in the cell wall and membrane43. This phenomenon enhances the permeability of solvent molecules into the cell, resulting in a stronger interaction between extraction solvent and phytochemicals44. It has been reported that the polar nature of phenolic compounds is influenced by an increased polarity index of the solvent, which is attributed to the increased solvent volume, consequently this leads to an increase in the extraction of these bioactive compounds45.

In MAE, treatment time plays a pivotal role in influencing the extraction of bioactive compounds from the plant material46,47. When samples are exposed to microwave radiation for a longer time the greater disruption of cell walls occurs, facilitating greater mass transfer from the interior of the sample to the solvent, resulting in an efficient increase in TPC48,49,50. Excessive exposure to microwave irradiation can lead to overheating of the plant material. Optimization is crucial to determine the optimal duration of microwave treatment51.

The negative impact of ethanol concentration was also observed in the response surfaces, as depicted in Figs. 2d and 3a. The response values were observed to be higher when the ethanol concentration was closer to the lower values. According to Yang et al.52, at lower concentrations, ethanol can penetrate the plant cells more easily and facilitate the extraction of polyphenolic compounds53. On the other hand, higher concentrations of ethanol may lead to protein denaturation and dehydration of the plant cells, hindering the extraction process and resulting in lower yields54,55.

Higher temperatures were associated with lower response values for both total phenolic content (Fig. 2a,b) and antioxidant activity (Fig. 3a,b). This is due to thermal degradation of sensitive compounds at elevated temperatures. Increased kinetic energy at higher temperatures can break down or alter the structure of target compounds, reducing extraction efficiency56.

Simultaneous multi-response optimization

The optimal conditions for MAE were determined using a numerical optimization approach. Numerical optimization ramps were employed to determine the optimum values for temperature, extraction time, extraction volume, and ethanol concentration, with the objective of maximizing the response variables. The optimal MAE conditions were determined using desirability as a criterion. Based on RSM, the optimum conditions were found to be a temperature of 60 °C for 22 min, using 11 mL of 51% (v/v) ethanol, with a desirability score of 0.924 (Table 4). To validate the predicted response variables, experimental assays were conducted in triplicate under these optimal conditions. The experimental results obtained for TPC, and antioxidant activity (FRAP) were in close agreement with the values predicted by the polynomial quadratic models, indicating the reliability and effectiveness of the optimized MAE-BBD-RSM method.

Table 4 Experimental values and predicted values of response variables at optimum extraction conditions.
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This approach allows for the reduction in the number of experiments required for polyphenol extraction with antioxidant properties without compromising the validity of the results.

Chemical profile of CN optimal extract

After identifying the optimal conditions for MAE, the next step was to characterize the extract obtained under optimized parameters (60 °C; 22 min; 11 mL; 51% v/v EtOH). This characterization aimed to assess the composition and properties of the extract, providing valuable information about its chemical profile and potential bioactive components. The liquid chromatography–mass spectrometry method was optimized, operating under both, negative and positive modes, to find the best fragmentation pattern for each compound (Fig. S1). LC/MS–MS platform allowed us to tentatively identify a total of 63 compounds, primarily belonging to the class of flavonoids, saponins, fatty acids, and lipids.

The complete list of the compounds tentatively identified in optimal CN extract is reported in Table 5.

Table 5 Complete list of tentatively compounds identified in CN extract.
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Among the identified flavonoids (28), CN extract was found to be rich in flavonol glycosides with kaempferol and quercetin as the main aglycones.

According to the negative fragmentation pattern, peaks 3, 4, and 12 were tentatively identified as isomers of Kaempferol 3,7-O-dihexoside, with a molecular ion [M − H] at m/z 609. In MS2, these compounds exhibited a disaccharide moiety, and the loss of 324 Da resulted in the aglycone deprotonated ion at m/z 285. Peaks 13 and 15 were tentatively identified as isomer of Kaempferol attached to a single sugar moiety. The [M − H] ion at m/z 447 corresponded to the molecular formula C21H20O11, and it produced fragment ions at m/z 285 [M − H-162]. Compounds 17 and 34 were tentatively identified as kaempferol in positive and negative ionization mode, respectively.

The chromatogram of CN analyzed in positive ionization mode showed a peak 5 with [M + H]+ ion at m/z 627. Fragment ions at m/z 465 and at m/z 303 were observed, corresponding to the loss of a sugar moiety [M + H–162]+ and to the aglycone portion, respectively. This peak was identified as Quercetin 3,4ʹ-didihexoside. Peaks 8 and 14 showed a molecular ion at m/z 463 [M − H], they have been identified as isomers of Quercetin 3-O-hexoside. The deprotonated molecular ion further generated an ion at m/z 301 through the relative loss of sugar moiety (− 162 Da)57,60,61.

Several fatty acids were identified in CN extract. Peak 35 showed at m/z 327 [M − H] a fragmentation ions at m/z 309 and m/z 229 produced by loss of water molecule and end-group HO-CH=CH(CH2)3CH3, respectively. This compound was tentatively identified as oxo-dihydroxy-octadecenoic acid (oxoDiHODE). A similar fragmentation pattern was also observed for 9,12,13-trihydroxy octadeca-7-enoic acid (TriHODE). Peaks 36, 37 and 39 which were detected at different retention times in the chromatogram, all exhibited ions at m/z 329 [M − H]ˉ. The MS/MS fragmentation pattern showed ions at m/z 311 [M − H–H2O]ˉ, 293 [M − H–H2O-H2O]ˉ and 229 [M – H–100]ˉ corresponding to the loss of water and end-group HO-CH=CH(CH2)3CH3, respectively62,68.

Chromatographic peaks 52 and 53 exhibited the precursor ion at m/z 295, but the loss of a water molecule [M − H–18] and the relative cleavage of the C=C bond adjacent to the hydroxyl group gave fragments at m/z 277 and m/z 195, leading to its tentative identification as 13-hydroxyoctadecadienoic acid (13-HODE)74.

LC-HRMS/MS in negative ionization mode, enabled the detection of five putative saponins in CN extracts. Saponins were observed as deprotonated formic acid (FA) adducts and the fragmentation pattern generally corresponding to the neutral loss of FA (46 Da) and/or glycosyl moieties, i.e. hexosyl (Hex), deoxyhexosyl (dHex), pentosyl (Pen) (Table S1). In addition, it was possible to tentatively identify saponins aglycon ions (sapogenin) by analysing diagnostic fragments associated with the sequential loss of the FA and glycosyl groups.

Peaks 26 and 28 exhibited an [M − H] ion at m/z 963 (C46H75O21) with MS/MS fragments at m/z 917, 771 and, 609 corresponding to the successive loss of formic acid (46 Da), deoxyhexosyl (C6H10O4) and hexosyl groups (C6H10O5, m/z 162), respectively. Thus, after the loss of dHex + Hex + FA, the unresolved portion was tentatively identified as sapogenin IV4 (C27H43O5, m/z 447), along with an additional hexosyl moiety. Based on these findings, these peaks were identified as Saponin 3-IV4-1.

Saponin 2-III3 (compound 49) showed a precursor ion at m/z 753 (C39H61O14) and generated MS/MS base fragment ions at m/z 707 and m/z 561 through the loss of formic acid (46 Da) and deoxyhexosyl (146 Da), respectively. Furthermore, a sequential cleavage of a pentosyl moiety (132 Da) resulted in a putative identification as sapogenin III3 (C27H41O4, m/z 429)65.

Phytosphingosine (peak 47) and Dehydrophytosphingosine (peak 44, 46) were detected in the samples analyzed using positive ionization mode. Peak 47 showed a precursor ion at m/z 318 [M + H]+. The most common fragments associated with this molecule were observed after the loss of a water molecule, resulting in the fragment ion at m/z 300 [M + H–H2O]+. Subsequently, the loss of another water molecule, led to the formation of the m/z 282 fragment [M + H–H2O–H2O]+. A similar fragmentation pattern was observed for Dehydrophytosphingosine (m/z 316, [M + H]+), where two consecutive losses of water molecules were observed, resulting in the formation of two fragments at m/z 298 [M + H–H2O]+ and m/z 280 [M + H–H2O–H2O]+.61.

Optimal CN extract protects HepG2 cells from oxidative stress induced by hydrogen peroxide

The antioxidant properties of CN extracts were assessed using two different cell-free assay, DPPH (Table S1) and FRAP tests. DPPH assay is the most used antioxidant assay for plant extracts. In this assay, a molecule or antioxidant with weak A-H bonding will react with a stable free radical DPPH· causing its discoloration76.

FRAP test is a chemical method used to assess the antioxidant activity of a sample in vitro. It is based on the sample’s ability to reduce a Fe3+ complex of tripyridyltriazine (Fe(TPTZ)3+) to Fe(TPTZ)2+ which is intensely in blue color at low pH77. Although these antioxidant assay are based upon well-known chemical reactions, this probably do not reflect the cellular physiological conditions78. Indeed, an antioxidant is not only a substance able to prevent another substrate from oxidation, but a molecule that protects the whole biological system from damages coming from oxidizing stressors79,80.

For these reasons, we evaluated the antioxidant activity of CN in hepatocarcinoma cell line Hep G2 treated with hydrogen peroxide. Firstly, in vitro cytotoxicity of CN extract by measuring the cell viability of Hep G2 using MTT assay was evaluated. Hep G2 is a popular hepatic cell line used in a broad range of biochemical applications, including cytotoxic studies since it is widely employed as in vitro model to study liver functions81. Hep G2 cells were incubated with CN extract for 24 h at different concentrations (1.56–200 µg/mL) followed by morphology evaluation and determination of cell mortality.

As shown in Fig. 4, the viability of cells treated without CN extract was defined as 100% (control group). 10% DMSO was used as positive control of mortality showing 12.54% of viability. The relative cell viabilities were always very high (viability > 90.64%) showing no cytotoxicity of CN extract compared to positive control.

Figure 4
figure 4

(Left) Cell safety evaluation of CN extract. Cell viability was performed using MTT assay. 10% DMSO was used as positive control. (Right) Measurement of intracellular ROS detected with DCFH-DA. H2O2 (800 μM, 1 h) was used as positive control. Data are showed as the mean ± SD of three different experiments performed in triplicate. **p < 0.01 vs. Ctrl; ***p < 0.001 vs. Ctrl; ##p < 0.01 vs. H2O2; ###p < 0.01 vs. 10% DMSO.

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Once the cell safety of optimal CN extract had been demonstrated, we proceeded to evaluate its ability to reduce intracellular release of ROS, induced by hydrogen peroxide. Our data highlighted that CN optimal extract (50–25 µg/mL) significantly inhibited ROS release in a concentration dependent manner in Hep G2 cells treated with H2O2.

Based on the obtained results, it can be concluded that spring onion leaves, which are considered an agricultural by-product, are a valuable source of antioxidant compounds. This finding suggests that they hold potential as functional ingredients for the production of new value-added products, such as functional foods and dietary supplements.

Conclusion

In the present study, we investigated, for first time, the nutraceutical potential of green onion stalks, a by-product of Cipollotto Nocerino PDO, a typical Allium cepa cultivar from Campania Region, Italy.

MAE platform was employed, leading to the valorisation of these residues, and enhancing the circular economy through improved waste management. For this purpose, BBD approach was effectively useful to maximize the extraction of TPC and FRAP from onion leaves.

Optimal MAE conditions to extract antioxidant compounds from CN leaves were determined using RSM (60 °C, 22 min, ethanol proportion of 51% (v/v), and solvent volume of 11 mL). These conditions provided a TPC value of 1.351 ± 0.07 mg GAE g−1 dw and an antioxidant capacity as measured by the FRAP assay of 14.016 ± 0.24 mmol Fe(II)E g−1 dw.

3D response curves showed that a moderate increase in ethanol concentration and higher extraction volume, coupled with extended extraction time and lower temperature, led to an enhanced yield of phenolic compounds and antioxidant activity in the final extracts.

A total of 63 compounds from various classes, including flavonoids, saponins, fatty acids, and lipids, were tentatively identified in the optimal CN extract using UHPLC-ESI-HR-MS/MS. Furthermore, we assessed the antioxidant potential of the CN extract on Hep G2 cells treated with H2O2. The results demonstrated a significant concentration-dependent inhibition of ROS release.

In conclusion, our study highlighted that spring onion leaves, often overlooked as agricultural by-products, are indeed a valuable source of antioxidant compounds. They could be used as functional ingredients for value-added products like functional foods and dietary supplements, thus providing innovative solutions for health and nutrition, while also contributing to the mitigation of environmental issues.