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Development and Evaluation of Nutraceutical products from Soybean, Sorghum and Basil leaf using Response Surface Methodology

Article Information

Abiodun Olapade, Uchenna Umeohia*

Department of Food Technology, Faculty of Technology, University of Ibadan, Oyo State, Nigeria

*Corresponding Author: Uchenna Umeohia, Department of Food Technology, Faculty of Technology, University of Ibadan, Oyo State, Nigeria

Received: 23 May 2021; Accepted: 31 May 2021; Published: 21 June 2021

Citation: Abiodun Olapade, Uchenna Umeohia. Development and Evaluation of Nutraceutical Products from Soybean, Sorghum and Basil Leaf Using Response Surface Methodology. Journal of Food Science and Nutrition Research 4 (2021): 144-160.

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Abstract

A central composite orthogonal experimental design (CCOD) was used to develop a nutraceutical product from soy protein isolate, sorghum pyrodextrin and basil instant soluble powder using their levels incorporation as the independent factors while functional, and antinutritional parameters served as the responses. The haematological and biochemical parameters of albino wistar rat fed with the preferred nutraceutical product were determined. Sensory profiling by 30 panelists using a 9-point hedonic scale was conducted. The response surface analysis of the dependent variables of the products revealed both quadratic and linear fitted effects (P<0.05).The developed nutraceutical product had water absorption capacity, 1.69g/g, oil absorption capacity, 0.78g/cm3 bulk density, 6.82 pH, 1.40mg/g trypsin inhibitor, 0.73mg/100g phytate, 0.54mg/100g tannin, and 2.15HU/mg haemagglutinins. The nutraceutical product boosted the homopeitic activities, reduced the fasting blood glucose and cholesterol of the experimental rats, while biochemical analysis indicated no toxicological implication. A regression graph of the observed and predicted physicochemical properties of the product showed a highly fitted model of R2 = 0.999. Consumer acceptability tests showed that the developed nutraceutical product was accepted by the panelists.

Keywords

Nutraceuticals, Pyrodextrin, Basil, Bioassay, Soy isolate, Response Surface Methodology (RSM), Regression analysis, Model, Fitting, Regression, Optimization

Nutraceuticals articles; Pyrodextrin articles; Basil articles; Bioassay articles; Soy isolate articles; Response Surface Methodology (RSM) articles; Regression analysis articles; Model articles; Fitting articles; Regression articles; Optimization articles

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Article Details

1. Introduction

The increase in the spate of health-related diseases coupled with emerging trend in the demand for functional foods had fueled in the past few years the evolving aggregated interest by scientists geared towards producing foods targeted at meeting this current challenge. The world food market is currently interested in food that provide not only nutritive values but that also promote health benefits beyond those provided by their inherent components [1]. Due to risk of toxicity or adverse effect of drugs, consumers are turning massively to food supplements to improve health where pharmaceutical fails. This resulted in a worldwide nutraceutical revolution [2].

The term ‘‘nutraceutical’’ was coined from ‘‘nutrition’’ and ‘‘pharmaceutical’’ in 1989 by Stephen DeFelice. Nutraceutical can be defined as, a food or part of a food that provides medical or health benefits, including the prevention and/or treatment of a disease [3].  Nutraceuticals is a broad term used to describe any product derived from food sources that provides extra health benefits in addition to the basic nutritional value found in foods [4]. These nutraceuticals normally contain the required amount of vitamins, lipids, proteins, carbohydrates, minerals, or other necessary nutrients, depending on their emphases [5]. The presence of these bioactive ingredients in the processed foods has become quintessential in order to satisfy the demands of health conscious consumers. At present, nutraceuticals represent the fastest growing segment of today’s food industry [6]. Soybeans, Glycine max (L.) Merr. (Leguminosae) are one of the most important legumes [7].  Soybeans also contain many nutritious and functional phytochemicals such as isoflavones, phytic acids, saponins and oligosaccharides [8, 9]. Due to its high biological value and content good numbers of essential amino acids it can be used to prevent protein-calorie malnutrition among vulnerable groups in the community [10]. Several recent scientific studies [11] have shown that regular intake of traditional soya foods may help to prevent breast cancer, prostate cancer, colon cancer and menopausal problems of women. Due to presence of isoflavones and phytoestrogen in soyabean, it helps to prevents cancer by inhibiting the growth of existing tumor cells, and the risk of endometrial cancer. Regular intake of soya product helps to prevent disease by lowering total cholesterol, low density lipoprotein, blood pressure and prevent plague built up in arteries (atherocleorosis) [12]. Soy protein isolate (SPI), a soybean derivative protein powder, is one of the most important products in food processing as well as many other industrial uses [13]. Its preference is attributed to its ability to enhance nutritional (especially protein) and functional qualities of food products to which it is used as an ingredient [14-16]. Sorghum (Sorghum bicolor (L.) Moench) is a cultivated tropical cereal grass. It is the only viable food grain for many of the world’s most food insecure people [17]. Diversification of the use of this important grain through conversion to nutraceutical commodity like dextrin will open new vistas of application of sorghum and thereby enhance utilization. Eliminating low molecular-weight fractions can make the dextrin sugar-free and significantly improve its digestive tolerance and reduce hygroscopicity. An ideal soluble dietary fiber should exhibit instant and complete water solubility, low viscosity, neutral taste, high-fiber content, high digestive tolerance, excellent stability (heat and acid), and easy processability (good flow and direct compressibility). A novel soluble dextrin fiber, possessing all the above-mentioned characteristics, can overcome the stability and application limitations of most soluble fibers [18]. Ocimum gratissimum L. (Lamiaceae) is an herbaceous perennial plant commonly known as scent leaf because of its aromatic smell.  The genus, Ocimum with the general name Basil, belongs to the family of plants known as Labiatae [19].   The plant is known to contain alkaloids, tannins, flavonoids and oligosaccharides [20]. It is used in the treatment of various diseases like cancer [21], antinociceptive, anti-inflammatory [22], antidiahorreal [23], antibacterial [24], antifungal [25], wound-healing [26] and as nephroprotective [20]. Its ethanolic extract has shown various activities like analgesic [27], antifungal [28], aphrodisiac [29], hepatoprotective [30], antioxidant [31,32] and anti-diabetic activity [33]. The specific objective of this study was to develop effective nutraceutical products from combinations of locally sourced plant material using response surface methodology as a means of optimization of the desirable responses.

2. Materials and Methods

2.1 Procurement of materials

The seeds of soybean (Glycine max) and sorghum (Sorghum bicolor L. (Merr.)) were purchased from Bodija market, Ibadan, Oyo State, Nigeria.  Freshly cuts leaves of African Basil (Ocimum gratissimum) were procured from Ojo market, Ibadan, Oyo State, Nigeria.

2.2 Production of soy protein isolates (SPI)

The flow chart of preparation of soy protein isolate (SPI) is shown in Figure 1. The defatted soybean meal was produced using method of [34]. Briefly, soybean seeds (12kg) were sorted, cleaned and washed thoroughly with clean water. The washed seeds were soaked in 1:5 ratio of water for 8 hours and subsequently drained and dehulled. The dehulled seeds where dried, milled into fine flour using hammer mill and was deffated using soxhlet extraction method. The defatted meal was converted to isolate by the method reported by Zhongjiang et al. [35]. Defatted soy bean flakes where suspended in 10-fold water and adjusted to a pH of 7 with 2mol/L NaOH. After stirring for 1hour, the suspension was centrifuged at 8000rpm for 30minutes. The supernatant was further subjected to isoelectric precipitation by adjusting the pH to 4.5 with 2mol/L HCL. The protein precipitate was obtained by centrifugation (5,000 rpm, 30 minutes), resuspended in water and adjusted to a pH of 7 with 2mol/L NaOH. After removing a small amount of insoluble substances by centrifuging at 10,000 rpm for 30minutes, the protein solution was freeze dried and ground to yield SPI powder.

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Figure 1: Flow chart for the production of soybean protein isolate (SPI) [35]

2.3 Production of sorghum pyrodextrin

2.3.1 Isolation of sorghum starch: Sorghum starch was extracted by using the methods of Beta and Singh [36, 37] as shown in Figure 2. Sorghum grain (10kg) was steeped in 10 litres of NaOH (0.25%, w/v) at 5oC for 24hours. The steeped grains were washed and ground with an equal volume of water using a blender for 3minutes. The slurry was filtered through a 200-mesh screen. The material remaining on the sieve was rinsed with water. Grinding and filtering processes were repeated on this material. After rinsing, the material still remaining on the sieve was discarded.  The filtrate was allowed to stand for 1hour. The filtrate was centrifuged at 10,000rpm for 19 minutes. The grey coloured, top protein-rich layer was removed using a spatula. Excess water was added to re-suspend the sample, and centrifugation was done for 5minutes. Washing and centrifugation was repeated several times until the top starch layer was white. The starch was dried for 24 hours at 40oC.

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Figure 2: Flow chart of production of pyrodextrin from sorghum

2.3.2 Pyrodextrinization of sorghum starch: The method of Sankhon [38] and Ghali [39], with slight modification was employed in the production of sorghum pyrodextrin.  Briefly, 5kg of starch was placed in stainless trays and 2.2 M hydrochloric acid was added. The starch/HCl ratio was 80:1 (w/v). The acid was dispersed on the starch and the mixture was allowed to react for 16 hours at room temperature. After that the mixture was dried in an oven at 110 °C for 3 hours and grinded to pass through a 100 μm sieve.

2.3.3 Production of basil instant (Soluble) powder: The instant soluble basil powder was produced from freshly cut leaves of the Ocimum gratissimum as shown in Figure 3.  Basil instant (soluble) powder was produced using the method of Sinija [40, 41], with slight modification. Fresh basil leaves were steamed immediately after plucking to arrest the fermentation reaction. The leaves were crushed and the juice was expressed out manually with the aid of cheese cloth for production of instant soluble powder. The juice with total solids of 7-9% was freeze dried to obtain basil instant soluble powder.

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Figure 3: Production of Ocimum gratissimum instant (soluble) powder

2.4 Nutraceutical product formulation

Nutraceutical products were prepared in the laboratory. Each sample of the nutraceutical products were formulated from soy proteins isolates, sorghum pyrodextrin and basil instant soluble powder. The ingredients were measured accurately with weighing balance and mixed thoroughly using Kenwood Mixer according to experimental design in Table 1.

2.5 Experimental design for the nutraceutical product formulation

Response surface methodology (RSM) was used to determine optimum formulation for the responses of interest. A central composite orthogonal experimental design (CCOD) was created with 20 runs, 8 factorial points, 6 center points, and 6 axial points, with α value =1.52456. Response surface methodology (RSM) with a five-level three-factor mixture design was used to optimize the formula of the nutraceutical product. The effects of three independent variables: soy proteins isolate (A; 54.75-85.25g), sorghum pyrodextrin (B; 14.75-45.25g) and Basil instant (soluble) powder (C; 0.95-7.05g) on the physicochemical, functional, and sensory parameters of the nutraceutical products as well as effects on the haematological and biochemicall parameters on albino wistar rats after standardisation test were determined. The range and center point values of three independent variables presented in Table 1 was based on the results of preliminary experiments. Each variable to be optimized was coded at five levels (−α, −1, 0, +1, +α).  Star points were carried out using α of 1.52465. Twenty randomized experiments including six replicates as the centre points were assigned based on CCOD.

In brief, the specified amount of the ingredients (soy protein isolate, sorghum pyrodextrin and basil instant tea powder) were measured accurately for each run and mixed thoroughly for even distribution of the component in a laboratory mixer.

The relationship of the independent variables and the response was calculated by the second-order polynomial Equation (1).

image

Y is the predicted response; βo is a constant; βi is the linear coefficient; βij is the cross product coefficient; and K the number of factors [42]. The second order polynomial coefficients was calculated using Statease design expert software package version 7.0.

2.5.1 The optimization process: A stepwise multiple regression analyses were conducted on the data from the Central Composite Ortogonal Design to relate amounts of soy protein isolate, sorghum pyrodextrin and basil instant (soluble) powder to the functional, antinutritional, and colour parameters of the samples. The response surface models were generated and presented as 3-dimensional plots in the function of 3 factors (soy protein isolate, sorghum pyrodextrin basil instant soluble powder). Adequacy of the model equation for predicting optimum response values was tested in the experiment using the soy protein isolate of 54.75–82.25g, sorghum pyrodextrin of 14.75-45.25g and amount of basil instant (soluble) powder of 0.95–7.05g. The optimal formulation of the nutraceutical products was determined from the mathematical models. In order to get these optimal values, the first partial derivatives of the regression equations was done according to X1 (A), X2 (B) and X3 (C) and sorted.

 

Soy Protein Isolate (g) A

Sorghum Pyrodextrin (g) B

Basil Instant Tea Powder (g) C

Runs      

Coded

Uncoded

Coded

Uncoded

Coded

Uncoded

1

-1.52465

54.75

0

30.00

0

4.00

2

0

70.00

0

30.00

0

4.00

3

0

70.00

0

30.00

0

4.00

4

0

70.00

+1.52465

45.25

0

4.00

5

-1

60.00

+1

40.00

-1

2.00

6

-1

60.00

-1

20.00

-1

2.00

7

+1

80.00

-1

20.00

-1

2.00

8

+1.52465

85.25

0

30.00

0

4.00

9

-1

60.00

+1

40.00

+1

6.00

10

0

70.00

0

30.00

-1.52465

0.95

11

0

70.00

0

30.00

0

4.00

12

+1

80.00

+1

40.00

+1

6.00

13

0

70.00

0

30.00

0

4.00

14

0

70.00

-1.52465

14.75

0

4.00

15

0

70.00

0

30.00

+1

7.05

16

0

70.00

0

30.00

0

4.00

17

0

70.00

0

30.00

0

4.00

18

+1

80.00

+1

40.00

1

2.00

19

-1

60.00

-1

20.00

1

6.00

20

+1

80.00

-1

20.00

1

6.00

Table 1: Levels of dependent and independent variables

2.6 Analyses of the nutraceutical products

Functional, antinutritional and colour parameters analyses were done on the samples of the nutraceutical products. The optimized sample of nutraceutical products was feed to albino wistar rats and the effects recorded through bioassay and subsequently subjected to sensory analysis to ascertain the level of acceptability of the developed product.

2.6.1 Functional properties: Water absorption capacity and oil absorption capacity was determined by the method of Sosulski [43], while bulk density was determined by the method of Pan [44]

2.6.2 Determination of anti-nutritional factors and phytochemicals: Trypsin inhibitor activity was determined by the method of Kakade [45], phytate by the method of Maga [46], tannin was determined by the method of Kirk and Sawyer [47], while haemagglutinin was determined by the method of Pull [48]

2.6.3 Bioassay: The optimized nutraceutical product was selected and used for bioassay study using 20 albino rats, their cholesterol level and blood sugar was determined by the method described by Sood [49], biochemical and haematological parameters were determined by Coles [50], liver and kidney function test was determined by Burtis and Ashwood [51].

2.6.4 Sensory analysis: Sensory evaluation of the samples was carried out using a 30-member panel; for various sensory attributes. A 9- point hedonic scale, where 9- like extremely, 8- like very much, 7- like moderately, 6 – like slightly, 5- neither like nor dislike, 4- dislike slightly, 3- dislike moderately, 2- dislike very much, 1- dislike extremely, as described by Ihekoronye and Ngoddy [52] was used to rate the taste, colour, flavour, mouthfeel and overall acceptability of the samples.

2.6.5 Statistical analysis: All the statistical analysis and graphical presentations were done using Statease Design Expert Software Package version 7.0. The significant probability was set at P < 0.05.

3. Results and Discussion

3.1 Effects of independent variables on the functional and antinutritional properties of the nutraceutical products

The functional and antinutrional properties of the nutraceutical products as affected by the varying proportions of soy protein isolate, sorghum pyrodextrin and basil instant soluble powder is presented in Table 2.  From the results, water absorption capacity ranged between 2.698g/g and 3.366g/g, oil absorption capacity, 1.538g/g and 1.775g/g, bulk density, 0.715g/ml and 0.809g/ml, pH, 6.594 and 6.920, trypsin inhibitor activity, 1.132mg/g and 1.577mg/g, phytate, 0.609mg/100g and 0.810mg/100g, tannin, 0.532mg/100g and 0.610mg/100g and haemagglutinins, 1.774HU/mg and 2.399HU/mg.

Table icon

Table 2: Functional properties and antinutritional components of the nutraceutical products

The dependency of functional and antinutritional properties of the nutraceutical samples on the independent variables of soy protein isolate, sorghum pyrodextrin and basil instant soluble powder is shown in the regression equations in Table 3. From the regression equations, water and oil absorption capacities, bulk density and pH possessed linear relationships, while trysin inhibitor activity, phytate, tannin and haemagglutinins had a mix of linear and quadratic effects. The effects of the independent factors on the functional and antinutrional properties of the nutraceutical products is depicted in 3D response plots in Figure 4.

Water Absorsption Capacity

+3.04332 +9.37746E-003*A - 0.019708*B -0.019789*C

0.9789

Oil Absorption capacity 

+1.65768 + 3.31444E-003*A - 6.38082E-003*B - 0.011273*C

0.9341

Bulk Density 

+0.76621 +1.32577E-003*A - 2.55233E-003*B - 4.50927E-003*C

0.9529

pH

+6.74500 + 2.56898E-003*A - 6.75805E-003*B - 2.03283E-003*C

0.5453

Trypsin Inhibitor

+1.29970 + 0.014052*A - 0.025860*B - 0.024941*C + 6.68408E-005*A*B + 7.27080E-005*A*C + 2.57688E-004*B*C -7.21194E-005*A2 + 1.16853E-004*B2 -1.33931E-004*C2

0.9989

Phytate

+0.73755 + 5.07859E-003*A - 0.012170*B - 0.013002*C +3.00784E-005*A*B +3.27186E-005*A*C +1.15959E-004*B*C -2.35613E-005*A2 +6.14764E-005*B2 + 1.62042E-004*C2

0.9993

Tannin

+0.55876 -1.12125E-003*A + 4.59850E-003*B - 8.83440E-003*C - 1.50547E-005         *A* B +5.10070E-005*A*C +2.32601E-005*B*C + 4.96553E-006* A2 -2.33804E-005*B2 -3.40112E-007 *C2

0.9991

Haemagglutinins

+2.14497 + 0.016680*A - 0.037402*B - 0.043190*C +9.21405E-005*A*B +1.19481E-004*A*C +3.78452E-004*B*C -7.92431E-005*A2 +1.85319E-004*B2 +3.91564E-004*C2

0.9997

Table 3: Regression equations of functional and antinutritional properties of the nutraceutical product formulations

fortune-biomass-feedstock

Figure 4: 3D Response surface plots of the effects of independent factors on the functional and antinutrional composition of the nutraceutical products

*A= water absorption capacity, B= oil absorption capacity, C= bulk density, D= pH, E= trypsin inhibitor, F= phytate, G= tannin, H= haemagglutinin

3.2 Optimization and validation of nutraceutical product formulation

In order to determine the optimum formulation, the regions of acceptability in the contour plot for each attribute were superimposed. Optimization was performed on the basis of a multiple response method called desirability. This procedure involved transforming scores on each of the dependent variables into desirability scores that could range from 0.0 for undesirable to 1.0 for very desirable. Thus considering the above mentioned approach, the objective was to hold in range functional, antinutritional, and colour parameters. Superimposition of contour plot regions of interest (within which, each attribute received ratings greater than or equal to 3.0) resulted in optimum regions for nutraceutical product formulation. The optimum nutraceutical product formulation were determined as all combinations from 54.75g to 85.25g soy protein isolate, from 14.75g to 45.25g sorghum pyrodextrin and from 0.96g to 7.05g basil instant soluble powder. Based on the superimposed plots, the selected optimal ingredient (independent variable) levels were 60.0g soy protein isolate, 20.0g sorghum pyrodextrin, and 4.83g basil instant soluble powders. The calculated desirability for this formulation was 0.679 and resulted to nutraceutical product of good quality. In order to verify the optimum formulation, the nutraceutical product using the optimal ingredient level was analyzed and the results were statistically compared to the predicted values of the mathematical model. The predicted response values and the actual obtained response values for the optimized products were within the range and found to be not statistically different at the 95% confidence level. The predicted and actual responses of the developed nutraceutical product are shown in Table 4.

Table icon

Table 4: Predicted and Observed values for the physicochemical properties of the nutraceutical product properties.

The matching quality of the data obtained by the optimization model proposed was evaluated considering the correlation coefficient, R2, between the experimental and modeled data. The mathematical adjustment of those values generated a R2 = 0.999, revealing that the model could not explain only 1% of the overall effects, showing that it is a robust statistical model. The parity plot shows a satisfactory correlation between the experimental and predictive values (Figure 5).

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Figure 5: Parity plot showing the distribution of experimental versus predicted values by the mathematical model of the y values

3.3 Haematological and Biochemichemical parameters of albino wistar rats fed with the developed nutraceutical product

The various biochemical and haematological parameters investigated in this study are useful indices of evaluating the toxicity of plant extract in animals [53]. Assessment of haematological parameters cannot only be used to determine the extent of deleterious effect of extracts on the blood of an animal, but it can also be used to explain blood relating functions of a plant extract or its products [54]. Analysis of blood parameters is relevant in risk evaluation as changes in the haematological system have higher predictive value for human toxicity when the data are translated from animal studies [55]. The comparative effects of the developed nutraceutical product and controlled diet on the haematological and biochemical parameters of the albino wistar rat is presented in the bar charts in Figures 6 and 7 respectively.

fortune-biomass-feedstock

Figure 6: Haematological parameters of albino wistar rat fed with the nutraceutical product and controlled diet

*WBC = White blood cell count, RBC = red blood cell count, PVC = packed cell volume, MCH = mean corpuscular haemoglobin, MCHC = mean corpuscular haemoglobin concentration and MCV= mean corpuscular volume

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Figure 7: Biochemical parameters of albino wistar rat fed with the nutraceutical product and controlled diet

*ALP = alkaline phosphatase, ALT = alanine aminotransferase, and AST = aspartate aminotransferase

The result showed that there was non-significant effect of the nutraceutical product on the haematological parameters of the rats as compared to the controlled sample. The non-significant effect of the extract on the haematological parameters may be an indication that the balance between the rate of production (erythropoiesis) and destruction of the blood corpuscles was not altered. From the result, there was slight increase in the haematological parameters of rats fed with the nutraceutical product compared with the controlled sample, indicating that the developed nutraceutical product could be homeopetic and helps in building of blood. This could be as a result of the relative high iron content of the nutraceutical product and iron had been known to be an integral part of haemoglobin moiety. Alkaline phosphatase (ALP), alanine aminotransferase (ALT), aspartate aminotransferase (AST), bilirubin, albumin, total protein, urea and creatinine which measured the extent of alteration of normal biochemical reactions in the animals were significantly same for both groups. This may imply that the developed nutraceutical product had no toxicity implication as the biochemical parameters of the rats fed with it were similar to the ones fed with normal rat chows. On the contrary, the blood glucose level and cholesterol of the rats fed with the nutraceutical product significantly reduced. This implied that the developed nutraceutical product could had blood sugar and cholesterol lowering potentials.

3.4 Sensory profile of the nutraceutical product      

The sensory analysis of the developed nutraceutical product using hedonic rating system revealed that the product was accepted by the panelists. It was observed that the mean rating for overall acceptability of the product was 7.17 (moderately liked). The mean rating for colour was 7.63 (like moderately), mouthfeel/texture had 7.43 (moderately liked), while taste had 6.97 (slightly liked). Flavour was rated the lowest having mean value of 6.90 (slightly liked).

4. Conclusion

Response surface methodology (RSM) was successfully applied to optimize the development of soy-sorghum-basil nutraceutical product. The three variables employed in the study had a significant effect on the functional, and antinutritional parameters of the nutraceutical products. Modelling of experimental data allowed the generation of useful regression equations for general use, to predict the behaviours of the products under different factor combination. The nutraceutical product developed from the models had no toxicological effects and significantly lowered the blood glucose and cholesterol levels of the albino wistar rats fed with it. The product was equally accepted by the sensory evaluation panelists.

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