Production of functional orange juice by the addition of coenzyme Q10

Today, in parallel to growing in acceptance of functional products, various additives are used to improve the characteristics of functional food products. The coenzyme Q10 plays a vital role in cellular energy production. It also increases the body's immune system via its antioxidant activity. The aim of this study was to evaluate the addition of coenzyme Q10 on physicochemical properties of orange fruit juice. The variables were concentrations of coenzyme Q10 (10 or 20 mg in 300 ml) and storage temperature (25 ° C and 4 ° C) and the parameters were pH, titrable acidity, brix, viscosity, turbidity and sensory evaluation during three months of storage . By increasing time and temperature, pH was decreased and with increasing concentration of coenzyme Q10, pH was increased. Time and temperature had direct influence on acidity, and the concentration of coenzyme Q10 had the opposite effect on the acidity. With increasing storage time and concentration of coenzyme Q10, Brix, viscosity and turbidity levels were increased and with increasing time and concentration of coenzyme Q10, the Brix, viscosity and turbidity were increased. The addition of coenzyme Q10 in grape juice showed no negative effect on the physicochemical and sensory properties.

Production of Probiotic Fermented Mixture of Carrot, Beet and Apple Juices

     In this study, production of fermented functional beverage based on the mixture of carrot, beet and apple juices using the Lactobacillus casei was carried out. Factors of consumption of reduction sugars, brix and bacterial growth were examined after fermentation and during the storage for 28 days and at 4˚C. To produce probiotic fermented mixture of Carrot, Beet and apple juices and Lactobacillus casei suspension with initial concentration of about 1.5x107 , 1.5x106 cfu/ml was prepared  and added to the mixture of juices  to the amount of  20, 30 and 40% , respectively. The fermentation process was completed during 48 hours and at 37 ˚C. Data analysis was conducted using the multiplied Duncan test including 6 test treatments and 1 control treatment and was repeated 3 times. During the fermentation process within all of the treatments, the number of probiotic bacteria increased due to the usage of sugar and nutrients inside the juice while sugars and brix levels decreased. The results revealed that the sample of A3B1 with concentration of 40% and 1.5x106 cfu/ml of Lactobacillus casei was considered as the best treatment which had the maximum rate of cell viability during 4 weeks of storage at 4 ˚C. In the sensory evaluation that  was conducted by the examiners after the first and the forth weeks at 4˚C, control treatment had the highest score and A3B1 treatment had the lowest score with concentration of 40% and the 106 cfu/ml of  probiotic bacteria

Characterization of Encapsulated Folic Acid in Saccharomyces cerevisiae Cells and Assessment of the Biochemical Stability after Baking and During Storage of two types of Iranian Breads

Background and Objective: Incorporation of folic acid (vitamin B9) to breads is a solution to avoid folic acid deficiency. However, the vitamin stability is highly concerned, especially at high temperatures. Hence, encapsulation can be a useful protective strategy. In this study, stability of encapsulated folic acid was investigated in Saccharomyces cerevisiae after baking and during storage of Iranian breads (lavash and barbari) .Material and Methods: Saccharomyces cerevisiae PTCC 5052 was treated via plasmolysis, autolysis and ultrasonication to compare protections of the vitamin. Loading capacity and encapsulation efficiency of the loaded cells were calculated. Thermal behaviors of the vitamin and yeast cells were studied using differential scanning calorimetry. Stability of free and encapsulated folic acid was assessed in the breads after baking and during storage (24 h for barbari and 24, 48 and 72 h for lavash) using high-performance liquid chromatography. Results and Conclusion: Plasmolyzed, autolyzed and ultrasonicated yeast cells included encapsulation efficiency of 52.50, 56.38 and 47.11% and loading capacity of 18.80, 20.65 and 15.34%, respectively, more than those the intact cells did. Plasmolysis, autolysis and sonication did not lead to significant changes in morphology of the cells. Transmission electron microscopy images verified entrapment of the vitamin within the cells. Differential scanning calorimetry analysis showed endothermic dips at 60–70 °C for the intact and treated cells, which were linked to the protein degradation in the yeast cells. No significant peak/dip was observed in differential scanning calorimetry graphs of the intact and treated yeasts at higher temperatures, showing thermal stability. In the two types of breads, the autolyzed yeast cells showed the best vitamin protection after baking and during storage. Encapsulation of folic acid in Saccharomyces cerevisiae is a practical approach in stability of folic acid in foods at high temperatures. Conflict of interest: The authors declare no conflict of interest.   Introduction   During the last two decades, interests in healthy living and eating have increased [1]. Introducing novel food formulations with health benefits can increase health of the consumers [2]. Folic acid or vitamin B9 is commonly used in fortified foods, especially flours and rice [3]. Production of food supplements and/or fortified foods is a favorable strategy to achieve sufficient folic acid within a day [3,4]. Encapsulated compounds effectively can improve their stability and bioavailability in foods [5]. The wide range of folic acid derivatives, their high sensitivity to light, heat and oxidation make folic acid analysis in foodstuffs quite difficult [6]. Low stability of folic acid is a big challenge for food scientists and nutritionists because inherent degradability of folic acid decreases its bioactivity [2,7–8]. To provide bioactive compounds with a high chemical stability, their encapsulation within protective and stable shells has been interested in recent decades [9]. Yeast cells have successfully been used for encapsulation of bioactive components [10]. These cells can stabilize susceptible bioactive components under harsh conditions. Of yeasts, Saccharomyces cerevisiae (baker's and brewer's yeast) has emerged as a promising host for developing novel types of drug delivery systems [11,12,10]. It provides a lipid bilayer with a network of mannoproteins and fibrous β-1,3-glucans [11,12,10]. The β-glucans and mannooligosaccharides are the major structural sugars of the yeast cell wall [11]. This specific structure can protect encapsulated compounds against destructive effects of light, heat, moisture and oxygen [10,11–13]. Due to the hydrophilicity of the yeast membrane, permeation of hydrophilic compounds is mechanistically facilitated [10]. However, encapsulation efficiency of the yeast cells may be affected, especially for fat-soluble compounds [11,12,14]. Modification methods have been developed to increase the yeast encapsulation efficiency and loading capacity [15]. It has been reported that mechanical disruption of cell walls by ultrasonication can lead to increased encapsulation efficiency by discharging the intracellular compounds into the surrounding media [11,13,15]. Use of chemical and biochemical methods is interested for the cell wall treatment. These are included in the utilization of chemicals or enzymes to alter the yeast cell wall. Yeast cell autolysis by endogenous enzymes is a process triggered by activating intracellular enzymes [11,13,15]. Glucanase and proteinase are the major enzymes contributing to disrupt-tion of the cell wall; through which, the cell wall becomes porous and crumpled leading to the release of intracellular compounds into the environment [11,16]. Moreover, plasmolysis is a chemical process, which provides a hyper-tonic environment in the presence of chemicals such as sodium chloride, toluene and ethanol [11,16,17]. It is addressed that pretreat-ment of yeast cells by plasmolysis using NaCl leads to increased encapsulation of cholecalci-ferol (vitamin D3) [13]. Similar results were observed after plasmolysis of yeast cells for encapsulation of purslane seed oil [15]. In recent years, bread enrichment with folic acid has been carried out as a national strategy in Iran [18]. However, susceptibility of folic acid to high temperatures of bread baking is highly concerned. No study has been carried out on efficiency of treated yeast cells in protection of folic acid under thermal process and during storage of breads. For the first time, this study aimed to treat cells of S. cerevisiae using plasmolysis, autolysis and ultrasonica-tion as carrier of folic acid for enrichment of two types of Iranian bread (lavash and barbari). Morphology of the cells, encapsulation efficiency (EE), loading capacity (LC), thermal behaviors and stability of encapsulates during baking and storage of the bread were assessed in the study. Materials and Methods 2.1. Materials The S. cerevisiae cells were provided from Fariman, Mashhad, Iran. All chemicals, including phosphate buffer, were purchased from Sigma Aldrich, USA. Sodium hydroxide and hexane were purchased from Merck, Germany. 2.2. Preparation of non-treated yeast cells Briefly, 170 g of S. cerevisiae cells were washed with phosphate buffer (pH 6.8) and centrifuged at 3984× g for 10 min. Then, cells were rinsed five times with deionized water. Cells were freeze-dried and stored at 4 °C for further experiments [15]. 2.3. Yeast cell plasmolysis Generally, 100 g of the prepared yeast cells were suspended in 1000 ml of NaCl solution (10% w v-1) and incubated at 55 °C for 48 h at 180 rpm. Then, plasmolyzed cells were rinsed with deionized water five times to separate the residual NaCl solution. Washed yeast cells were freeze-dried and stored at 4 °C for further analyses [15]. 2.4. Yeast cell autolysis Yeast cell suspension (15% wv-1) was prepared and pH was adjusted to 5.5 using HCl solution (4 N). To autolyze the yeast cells, 100 ml of the suspension were agitated for 48 h at 55 °C using shaking incubator. Autolyzed cells were centrifuged at 8000× g for 20 min [11]. 2.5. Yeast cell ultrasonication Yeast cell suspension (0.5 g/100 ml) was subjected to an ultrasonic bath (maximum power of 750 W, frequency of 20 kHz) and 20% of power were applied for 60, 180 and 300 s (10 s on-10 s off). Then, cells were accumulated by centrifugation at 4000× g for 5 min at 30 °C. The biomass was collected and assessed for further analyses [11]. 2.6. Encapsulation of folic acid within plasmolyzed, autolyzed and ultrasonicated cells Briefly, 10 g of folic acid were added to 40 ml of deionized water and mixed well using ultra-turrax (Turrax IKA T25-Digital Ultra, Germany) at 11800 g for 5 min. Ice bath was used to control the temperature. Then, intact, plasmolyzed, autolyzed and ultrasonicated yeast cells were separately added to the vitamin solution at 2:1 (w w-1) based on pre-experiences and then incubated at 40 °C for 12 h with a 180-rpm agitation rate. Then, folic acid-loaded yeast cells were centrifuged at 8965× g for 15 min and rinsed with deionized water to eliminate the residual non-loaded vitamin. Folic acid -loaded yeast cells were freeze-dried at -80 °C for 14 h and stored at 4 °C for further uses [19-21].   2.7. Assessment of efficiency and loading capacity In general, 10 mg of folic acid-loaded yeast cells were suspended in 5 ml of 0.1-N NaOH, stirred for 15 min and then ultrasonicated under output power of 0 400 W and output frequency of 20 kHz with a titanium horn with diameter of 13 mm (Model UHP-400, Lithuania) for 2 min at room temperature (RM) in three cycles of 50% amplitude. Treated suspension was filtered using Whatman filter papers of 11 μm (Whatman, USA). Then, 1 ml of the filtrate was made up to 10 ml with distilled water (DW) and incubated at 37 °C. To assess concentration of encapsulated folic acid, absorbance of the final solution was measured using UV-vis spectrophotometer (WPA S2000 Lightwave, Ireland) at 306 nm. Furthermore, NaOH solution (0.1 N) was used as blank. Concentration of folic acid was assessed using calibration curve. The EE (%) and LC (%) were assessed using Eqs. 1 and 2 as follows:                                                                                                                                                                                                                                  Eq. 1                                                                                                                                                                                                                                 Eq. 2 2.8. Microstructure analysis Microstructure of folic acid-loaded yeast cells was firstly investigated using scanning electron microscopy (SEM) (Oxford Instruments INCA Penta FET × X3, Chapel Hill, USA) [19]. The microencapsulated folic acid powder was adhered to aluminum stand using silver glue. Samples were coated using gold metallizer. Imaging was carried out using electron beam accelerator of 25 kV at ambient temperature. Additional studies on morphological charac-teristics were carried out using transmission electron microscopy (TEM) (Zeiss EM900, Carl Zeiss, Thornwood, USA) [12]. Samples were immerged in glutaraldehyde solution (3% vv-1) overnight. Then, these were washed and centrifuged at 4500× g, followed by suspending in molten agarose (2%). After solidification, agarose gels containing the samples were cut into cubes and transferred into osmium tetroxide (1%) for 60 min, followed by washing with 0.1-M phosphate buffer (pH 7.2). These were dehydrated with ethanol at gradient concentration (25–100% vv-1) and acetone. Then, cubes were embedded in Spurr’s resin. Cubes were cut into thin layers with 80-nm thicknesses with a RMC MT-7000 ultramicrotome, stained with uranyl acetate and lead citrate and then studied at 50 kV using TEM [13]. 2.9. Thermal analysis Thermal behaviors of the yeast cells were studied using differential scanning calorimetry (DSC) (Shimadzu DSC-60, Japan) [17]. Samples (6–12 mg) were transferred into aluminum pans, tightly sealed and heated from 25 to 300 °C at a scanning rate of 10 °C min-1. Nitrogen was used as a purge gas at a flow rate of 30 ml min-1. 2.10. Stability of folic acid in breads Stability of folic acid in breads after baking and during storage (after 24 h for barbari and after 24, 48 and 72 h for lavash) was assessed using high-performance liquid chromatography (HPLC) (Model 7000, Merck-Hitachi, Darmstadt, Germany) equipped with a fluorescence detect-or (Model 7485, LaChrom, Merck-Hitachi, Darmstadt, Germany). A LiChrosphere100 RP-18 (5 mm) column (Merck, Darmstadt, Germany) was used to separate the compounds. Column was eluted with gradient concentra-tions of acetonitrile and 30 mmol l-1 phosphate buffer at pH 2.2 [potassium phosphate and ortho-phosphoric acid (85%), 10:1] at a flow rate of 0.9 ml min-1. The gradient program was started at 6% acetonitrile. Then, isocratic concentration of 6% was used for 6 min, followed by increasing to 25% acetonitrile until 24 min. At the end of the process, concentration of acetonitrile decreased to 6% after 5 min. Injection volume included 40 ml. The running time was 30 min and the injection interval was 40 min. Fluorescence absorbance at excitation and emission wavelengths of respectively 280 and 350 nm was used to quantify folic acid [16]. 2.11. Statistical analysis Data were analyzed using SPSS software v.22 (IBM, USA). All experiments were repeated three times. Compar-ison of means was carried out using one-way ANOVA followed by Duncan test to report significant differences at a confidence level of 95%.   Results and Discussion 3.1. Effects of plasmolysis, autolysis and ultrasonication on encapsulation efficiency and loading capacity In general, S. cerevisiae has attracted great attentions in microencapsulation [10]. Use of modifications on yeast cells has demonstrated positive effects on the EE [22]. Discharging the contents of yeast cells can increase space needed for entrapping. Plasmolysis, autolysis and ultr-asonication can provide necessary space for the entrapment of bioactive ingredients by driving the cell components outside [11,13]. Effects of cell wall treatments on EE and LC are present in Table 1. For folic acid-loaded intact cells, EE and LC were significantly lower than those for treated yeast cells. It was associated with the altering effects of the treatments on the cell wall, leading to leakage of intracellular compounds for providing further spaces for core loading [13]. Chemical treatment of yeast cells leads to the increased permeability [19,23,24]. Due to the inter-molecular interactions of mannoproteins, the hydrophobic linkages and disulfide bonds are responsible for the cell wall porosity. Physical and chemical treatments can destroy these intermolecular network; through which, it promotes permeability of the S. cerevisiae cells [23]. In comparison, ultrasonication affects the permeability by rupturing the cell wall through the microstreaming and bubble cavitation, causing shear stress on the cell wall [25]. In a previous study, β-carotene was encapsulated with Yarrowia lipolytica cells using improvement of the core entrapment and sonication [25]. Use of ultrasound, as a green physical treatment, significantly increased the β-carotene encapsulation efficiency in yeast [25]. In the current study, autolysis was the most efficient treatment for encapsulation of folic acid, followed by plasmolysis and sonication. Indigenous hydrolyzing enzymes in the yeast cells change the cell wall structure to provide available space for the entrapment of bioactive compounds. As seen in Table 1, EE and LC of autolysis were higher than those of other external chemical (plasmolysis) and physical (ultrasonication) forces. 3.2. Microstructure and morphology of folic acid-loaded yeast cells Morphology of folic acid-loaded intact and treated yeast cells was assessed using SEM (Fig. 1). As illustrated in Fig. 1a, intact yeast cells were agglomerated, while plasmolysis, autolysis and ultrasonication increased the cell distances, resulting in separation of the cells (Figs. 1b–d). After plasmolysis, contraction of cell wall resulted in the formation of further spaces between the cells. Furthermore, separation after autolysis was possibly due to the repulsive forces of the cells as a result of accumulation of similar charges on the cell surface in the acidic environment. In addition, the accumulated intact cells were disrupted after ultrasonication through the cavitations process. Nonetheless, discharging cells from internal components possibly led to alteration of the surface and physical hindrance. Relatively, no significant change was observed in integrity of the plasmolyzed yeast cells used for encapsulation of Gallic acid [26]. Similarly, purslane seed oil-loaded non-plasmolyzed, plasmolyzed and plasmolyzed CMC-coated yeast cells included spherical shape and no cracking, deformity or rupture was observed in their SEM images. The authors reported that plasmolysis did not change the integrity of yeast cells [15]. Figure 2 shows TEM images of the non-loaded and loaded intact and treated cells. As seen in the figure, folic acid was successfully entrapped in the yeast cells. The lowest entrapment was observed for the intact cells followed by the ultrasonicated cells (Table 1). Furthermore, treatment of the cells did not change the cell integrity and no inconformity was seen in the treated cells. 3.3. Differential scanning calorimetry Thermal behaviors of free folic acid and the loaded intact, plasmolyzed, autolyzed and ultrasonicated cells are illustrated in Fig. 3. Folic acid showed a constant thermal behavior until 220 °C and an endothermic dip was detected at 230 °C, which could be linked to the degradation of the vitamin [26]. For the loaded yeast cells, an endothermic dip was detected at 60–70 °C, which was attributed to the protein denaturation. Similarly, an endothermic dip at 67.87 °C was observed by Cruz-Gavia et al. in study of thermal behavior of S. cerevisiae cells. The authors believed that protein molecules of the cells denatured in this area [27]. In addition, gelatinization of β-D-glucan might show an endothermic dip at nearly 52 °C [28]. Despite no evidence of degradation at higher temperatures (Figs. 3b–e), degradation of the phospholipid bilayer and yeast cells was usually occurred at higher temperatures (160 and 265 °C) [19]. Interestingly, intact cells showed a sharper endothermic dip in the region (Fig. 3b), compared to the treated cells that might be attributed to its higher protein contents.   3.4. Vitamin stability Stability of folic acid within treated and non-treated yeast cells in Iranian breads of lavash and barbari was assessed (Table 2). Breads include various shelf lives in the environment. Barbari is a semi-volume bread and it stales after 24 h at ambient temperature. In comparison, the flat bread of lavash can be stored up to 3 d in the environment. Therefore, the two types of bread were studied under various times. Before baking (dough), the highest quantity of folic acid was preserved in L1, L3 and B1 while the lowest quantity was achieved in L2 and B4. After baking (0 h), the highest folic acid preservation in barbari was achieved in B1 and B2. Similar results were observed after 24 h; thus, breads containing folic acid-loaded autolyzed cells showed the best vitamin preservation. This was similar to the results of lavash breads; in which, folic acid-loaded autolyzed cells included the best vitamin preservation followed by folic acid-loaded plasmolyzed and ultrasonicated cells after baking and until the end of storage. Concentrations of folic acid in dough and breads showed significant differences. This verified the need of protective strategies for better preservations of the vitamin to avoid its significant losses under the processes. Similar results were reported by other studies. Ashkezary et al. enriched Iranian breads with encapsulated riboflavin in plasmolyzed and non-plasmolyzed yeast cells; through which, a better protection of the encapsulated vitamin was seen after baking and during storage of the breads, compared to free riboflavin. In their study, a better protection was detected in the plasmolyzed yeast cells [10]. Microencapsulation of limonene by yeast cells can protect it after drying and heavy washing with hexane [29]. Using the yeast cells for microencapsulation of polyunsaturated fatty acids (PUFA) led to a better protection against high temperatures and oxidation [21]. Similarly, higher preservations of cholecalciferol (vitamin D3) after exposure to simulated gastrointestinal tract (GIT) was reported through its encapsulation with yeast cells [30]. Neves et al. studied the thermal stability of folic acid in fortified French breads. Based on their results, a less loss of folic acid was seen in breads containing encapsulated vitamin, compared to that observed in breads with free folic acid (degradation started at 100 °C and completed at 155 °C after 30 min or 175 °C after 5 min for free folic acid, while it started at 40 °C and completed at 100 °C after 15 min for encapsulated folic acid). It was suggested that folic acid dispersion on the surface of the microcapsule caused their faster degradation, compared to free vitamins [31]. Villela et al. studied potentials of starch and polyethylene glycol for the encapsulation of folic acid. Accordingly, folic acid was successfully encapsulated within the polymers, but sizes of the particles varied 18–45 µm based on the type of starch (corn, potato and rice). In simulated gastric fluid, a partial degradation of polyethylene glycol (30–37%) was seen, while starch-folic acid core was intact. Moreover, a 50% degradation in polyethylene glycol was observed in simulated intestinal fluid. Degradation of polyethylene glycol provided controlled gradual releases of folic acid in the simulated gastrointestinal environment [32]. Yingleardr-attanakul et al. investigated folic acid fortification of rice vermicelli using various encapsulation techniques of gel particle, complex coacervation and spray drying. In their study, pectin and sodium alginate were used for the entrapment of the vitamin. The authors detected that spray drying was the most appropriate technique for folic acid encapsulation in rice vermicelli because spray dried particles were acid-soluble but water-insoluble; thus, preventing the loss of folic acid during processing [33]. Conclusion Microencapsulation of folic acid via plasmolyzed, autolyzed and ultrasonicated yeast cells improved the e

Characterization of Probiotic Fermented Milk Prepared by Different Inoculation Size of Mesophilic and Thermophilic Lactic Acid Bacteria

Background and Objectives: Importance of development of novel probiotic fermented milk and challenge made for its acceptability is well known. In this research, the impact of different inoculation sizes of yogurt and DL-type starter culture (mesophilic and thermophilic LAB) on titratable acidity, viscosity, sensorial and microbial properties of fermented milk was investigated; and finally, probiotic Langfil was produced.Materials and Methods: Fermented milk produced by 1, 2 and 3% v v-1 inocula consisting thermophilic: mesophilic starter cultures 10:90 (Lactococcus lactis subsp. lactis, Lactococcus lactis subsp. cremoris, Lactococcus lactis subsp. lactis, Lactococcus lactis subsp. lactis biovar. diacetylactis and Leuconostoc mesenteroides subsp. cremoris. Streptococcus thermophilus and Lactobacillus delbrueckii subsp. Bulgaricus) were analyzed for determination of titratable acidity, viscosity, viability of mesophilic starter cultures and sensory properties on days 5, 10, and 15 of storage at 4°C. Then, the most suitable treatments were selected for the producing probiotic Langfil, containing probiotic starter culture (2% v v-1 inoculums with equal ratio of Lactobacillus acidophilus and Bifidobacterium bifidum. Lactococcus lactis and L. cremoris were counted on M17 agar, while Leuconostoc and Lactobacillus were counted aerobically on tomato juice agar and MRS bile agar, respectively. Bifidobacterium was cultured anaerobically on MRS bile agar. Sensory evaluation was carried out by ten trained panelists, based on a nine-point hedonic scale during the cold storage.Results and Conclusion: According to results, the best organoleptic properties were achieved in the product prepared with 2% the mesophilic and thermophilic starter cultures and 2% probiotic. This product had a high viscosity. An Iranian probiotic Langfil with desired properties was produced using the best treatment prepared.Conflict of interests: The authors declare no conflict of interest

Evaluation of coenzyme Q10 addition and storage temperature on some physicochemical and organoleptic properties of pomegranate juice

Today, in parallel to growing in acceptance of functional products, various additives are used to improve the characteristics of functional food products. The coenzyme Q10 plays a vital role in cellular energy production. It also increases the body's immune system via its antioxidant activity. The aim of this study was to evaluate the addition of coenzyme Q10 on physicochemical properties of pomegranate fruit juice. The variables were concentrations of coenzyme Q10 (10 or 20 mg in 300 ml) and storage temperature (25°C and 4°C) and the parameters were pH, titrable acidity, brix, viscosity, turbidity and sensory evaluation during three months of storage. By increasing time and temperature, pH was decreased and with increasing concentration of coenzyme Q10, pH was increased. Time and temperature had direct influence on acidity, and the concentration of coenzyme Q10 had the opposite effect on the acidity. With increasing storage time and concentration of coenzyme Q10, Brix, viscosity and turbidity levels were increased and with increasing time and concentration of coenzyme Q10, the Brix, viscosity and turbidity were increased. The addition of coenzyme Q10 in grape juice showed no negative effect on the physicochemical and sensory properties.

Optimization of Aqueous Extraction Conditions of Inulin from the Arctium lappa L. Roots Using Ultrasonic Irradiation Frequency

Ultrasound-assisted extraction is a promising technique to obtain active compounds from plants with high efficiency. The present study was conducted in two sections. In the first phase, the effect of solvent type (methanol, ethanol, water, and water-ethanol (50 : 50, v/v)) on inulin extraction yield from burdock roots (Arctium lappa L.) was investigated by the conventional method. The second phase aim was to optimize the condition of inulin and phenolic compounds including sonication time (10–40 min), sonication temperature (40–70°C), and solid/solvent ratio (1 : 20–1:40 g/ml) using response surface methodology (RSM). The results demonstrated that the highest inulin efficiency was extracted by water in the conventional method, which is equal to 10.32%. The optimum conditions of ultrasound-assisted water extraction for independent variables including sonication time and temperature as well as solid/water ratio were 36.65 min, 55.48°C, and 1 : 35 g/ml, respectively, which were determined on the maximization of inulin and total phenol content and minimization of IC50. At this optimum condition, inulin yield, phenolic compounds, and IC50 were found to be 12.46%, 18.85 mg GA/g DW, and 549.85 µg/ml, respectively. Regarding the results of this research, ultrasound-assisted extraction can be used as an alternative to the conventional extraction methods in extracting bioactive compounds from medicinal plants because it may improve the mass transfer, reducing the extraction time and the solvent used