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Original scientific paper

https://doi.org/10.17113/ftb.61.03.23.7843

Ispitivanje tehnoloških i senzornih svojstava mafina pripremljenih s chia sjemenkama i liofiliziranim prahom breskve

Dasha Mihaylova orcid id orcid.org/0000-0002-6144-9640 ; Department of Biotechnology, University of Food Technologies, 26 Maritsa Blvd., 4002 Plovdiv, Bulgaria
Aneta Popova ; Department of Catering and Nutrition, University of Food Technologies, 26 Maritsa Blvd., 4002 Plovdiv, Bulgaria
Zhivka Goranova orcid id orcid.org/0000-0003-0830-8109 ; Institute of Food Preservation and Quality, Agricultural Academy, 154 Vasil Aprilov str., 4002 Plovdiv, Bulgaria
Pavlina Doykina orcid id orcid.org/0000-0003-0342-5090 ; Department of Catering and Nutrition, University of Food Technologies, 26 Maritsa Blvd., 4002 Plovdiv, Bulgaria
Bogdan Goranov orcid id orcid.org/0000-0002-5836-4136 ; Department of Microbiology, University of Food Technologies, 26 Maritsa Blvd., 4002 Plovdiv, Bulgaria


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Abstract

Pozadina istraživanja. Interes potrošača za hranom s dodatnom hranjivom vrijednošću sve je veći. U ovom je radu prikazana mogućnost pripreme mafina prema novoj recepturi, s chia sjemenkama i liofiliziranim prahom breskve, čime bi se smanjile društvene posljedice nezdravih prehrambenih navika i time povezane intolerancije na hranu.
Eksperimentalni pristup. Razvijene su dvije nove recepture pomoću kojih se izbjegava upotreba jaja i korigiraju količina i tip brašna. Novi su proizvodi procijenjeni pomoću sljedećih parametara: fizikalna svojstva, tekstura, aktivitet vode, broj stanica mikroorganizama, antioksidacijski potencijal i senzorna svojstva.
Rezultati i zaključci. Rezultati pokazuju da su relativna masa tijesta i njegove fizikalne značajke (gustoća, volumen i visina) obrnuto proporcionlni u svim uzorcima mafina. U usporedbi s kontrolnim uzorkom, u uzorcima pripremljenim prema modificiranoj recepturi smanjio se gubitak pri pečenju, povećao ukupni udjel fenola i povećao udjel vlakana a time i poboljšala hranjiva vrijednost mafina. Dodatkom chia sjemenki i praha breskve poboljšala su se njihova senzorna svojstva. Promjene izvorne recepture bitno su utjecale na boju mafina, koji su bili tamniji i manje žuti od kontrolnog uzorka. Tekstura novih uzoraka bila je bliža onoj kontrolnog uzorka.
Novina i znanstveni doprinos. Razvoj nove recepture koja neće umanjiti kakvoću proizvoda je bitan u tehnologiji hrane. Nova receptura treba zadovoljiti očekivanja modernih potrošača. Svrha je ovoga rada bila prikazati novi proizvod s poboljšanim funkcionalnim značajkama.

Keywords

kolač; zdravi nadomjestak; voćni sastojak; Prunus spp.; pekarski proizvodi; tehnološki čimbenici; senzorsko ispitivanje

Hrčak ID:

309765

URI

https://hrcak.srce.hr/309765

Publication date:

14.11.2023.

Article data in other languages: english

Visits: 767 *




INTRODUCTION

Food habits can significantly aid in maintaining good health and minimizing the manifestation of non-communicative diseases (1). The western diet is known for its high content of saturated fat, refined sugar and flour, low quantities of minerals, vitamins and antioxidants, which contributes to negative changes in the daily diet, decreased physical activity, gaining weight and poor health in general (2). For these reasons, recommendations of better and sustainable food choices are gaining popularity (3).

Baked goods like cookies, muffins, biscuits, cakes and waffles, among others, are desirable and preferred eating options due to their pleasant taste and market availability (4). If we have to evaluate their nutritional profile though, they are usually high in sugar, fat and energy and fall into the red zone of the traffic light food labelling system (5). Therefore, reformulating baked goods, in terms of a better nutritional profile, is a good option, especially considering the continuously rising level of overweight and obesity among children, adolescents and adults (6). What is more, introducing health-promoting ingredients such as antioxidants, fibre, minerals, and vitamins can positively alter these food formulations, promoting healthier eating habits, and long-term wellbeing of individuals (7,8).

The chia seed has a high nutritional potential due to its protein and fibre content, as well as a source of omega-3 and 6 fatty acids (9). Chia is also reported to aid the cardiovascular health (10), have antioxidant properties (11), exhibit anti-inflammatory properties (12), as well as better control of the lipid metabolism (13). Apart from that, whole grain consumption has been reported to contribute to a reduced risk of diseases like cardiovascular, diabetes, and some types of cancer (14). Einkorn flour has been successfully used in the preparation of dietetic dough (15). Additionally, fruits are very well-known for their beneficial properties (16), but are still limited to their consumption as fresh or dried. Furthermore, fruit-based products are usually associated with dairy (17). Genus Prunus representatives (peach, apricot, cherry, sour cherry, plum) are highly cherished for their sensory attributes and health-promoting properties (18). Numerous cultivars are gaining popularity due to their distinct profile, i.e. beneficial compounds, external properties and ripening period, among others. Peach ’Evmolpiya’ is a native Bulgarian variety, created by interspecific hybridization with the participation of Prunus persica, and Prunus davidiana, which ripens late in the summer season.

Nowadays, many studies focus on the effort to include ingredients with beneficial effects on human health that arise from the need to reformulate preferred but unhealthy foods. Muffins appear as a trending research area since scientific papers on their reformulation include the use of olive pomace flour (19), a kimchi by‐product (20), wheatgrass powder (21), sunflower flour (22) and green banana flour (23).

The main goal of this study is to determine the physical characteristics, texture profile, water activity, microbial load, antioxidant potential and sensory profile of reformulated muffins in order to enable the development of healthier products in terms of their nutritional value and quality characteristics.

MATERIALS AND METHODS

Materials

Fresh peach samples of the ’Evmolpiya’ variety were provided from the Fruit Growing Institute, Plovdiv, Bulgaria. The samples were lyophilized (vertical freeze dryer BK-FD12S; Biobase Biodustry Co., Ltd., Shandong, PR China) under the pressure of 3.5 MPa at −55 °C and powdered with Tefal GT110838 grinder (Rumilly, France) at 180 W for 30 s. The other products needed for the preparations were purchased from several stores in Plovdiv, Bulgaria, i.e. a local Lidl store (sugar, wheat flour, fresh eggs), a dm (organic chia seeds), and Balev bio (organic einkorn flour, organic baking powder). Wheat flour was produced and packaged by Good mills Jsc., Sofia, Bulgaria. The fresh eggs were produced and packaged by Medkovets Ltd., Gurmazovo village, Sofia province, Bulgaria. Sugar was produced and packaged by Zaharni zavodi, Gorna Oriyahovitsa, Bulgaria. Einkorn flour was produced and packaged by Ekosem Ltd, Stambolov village, Bulgaria. Chia seeds are imported from Peru (packaged by Internetkafe Ltd, Sofia, Bulgaria).

Preparation of muffin formulations

The muffins (Fig. S1) were prepared using one-bowl baking method under laboratory conditions at the Institute of Food Preservation and Quality, Agricultural Academy, Plovdiv, Bulgaria.Table S1 provides information about the mass fraction of the ingredients used to prepare the formulations.

The control sample was prepared by beating the eggs and the sugar with a Philips mixer (HR 3745/00; Amsterdam, the Netherlands) at 450 W for 3 min until a fluffy light yellow mass was obtained, then adding the wheat flour and homogenizing again. The dough was dosed into muffin tins and baked in a preheated electric oven at 180 °C for 30 min. The amount of eggs in the newly developed recipes (formulations F1 and F2) was completely replaced by chia gel. Before preparing the muffins, chia seeds were ground in a Tefal grinder (model GT110838) at 180 W for 30 s. Chia gel was prepared by hydrating the chia powder in a V(chia):V(water)=1:9 for 30 min. All dry ingredients (sugar, flour, peach powder and baking powder) were previously mixed, and then mixed with the other ingredients (eggs or chia gel and water) for an additional minute. The dough (55 g) was dosed into muffin tins and baked in a preheated electric oven at 180 °C for 45 min. The baked muffins were cooled for 30 min. The samples were stored under standard conditions (temperature of (20±2) °С and relative humidity ≤75 %).

Physical characteristics of the muffins

The height and volume of the muffins were measured using a digital calliper; the mass and baking losses were measured on an electronic scale. The baking loss was calculated by the following equation:

m(baking loss)=[(m(batter)–m(muffin))/m(batter)]·100 /1/

Ash and moisture content

Ash mass fraction was determined by burning the weighed mass of sample in a muffle furnace according to AOAC 945.46 (24). Total moisture mass fraction of the samples was determined according to the procedure described in AACC method 44-15.02 (25).

Nutritional data

The nutritional data were determined by the calculation method. The nutritional value of the finished products was calculated per 100 g based on specifications obtained from suppliers of each of the ingredients (sugar, flour, eggs and chia seeds). The nutritional value of the ’Evmolpiya’ peach was based on previous research (26).

Colour

The CIELAB colour of the crust and crumb was analyzed with the use of PCE-CSM 2 (PCE-CSM instruments, Berlin, Germany) with a measuring aperture of 8 mm. The assessed parameters included lightness (L, ranging from 0 to 100), red-green opponent colours (representing a), blue-yellow opponent colours (representing b), chroma (C), and hue angle (h). The total colour difference (∆E) was calculated according to the CIE76 colour difference equation:

FTB-61-273-e2.jpg /2/

where values for L*, a* and b* correspond to the CIELAB colour measurements.

Browning index

Colour changes due to browning reaction were assessed using a colorimeter (L*, a*, b*) and browning index (BI) was measured following the equation:

BI=[100·(x–0.31)]/0.172 /3/

where x=(a+1.75·L)/(5.645·L+a–0.3012·b).

Values for L*, a* and b* correspond to the CIELAB colour measurements.

Texture profile analysis

Texture profile analysis was performed by texture analyzer (TA.XT-2i Texture Analyzer Stable Microsystems, Godalming, Surrey, UK) with 0.15 N load cell following the AACC method 74-09 (27). The texture parameters (firmness, gumminess, chewiness, springiness and cohesiveness) were determined in a texture profile analysis mode. Texture analyzer test samples were prepared by cutting a cube from the middle of the muffins (2 cm×2 cm×2 cm), and tested with cylindrical probe of 36 mm, compression 60 %, pre-test, test and post-test speed of 2.0 mm/s and trigger force 5 g.

Determination of total phenolic and total flavonoid content

The total phenolic content (TPC) was analyzed following a modified method of Kujala et al. (28). The TPC was expressed in mg gallic acid equivalents (GAE) per g of dry mass. The linear range for gallic acid standard was 5-100 mg/L (R2=0.9965). The total flavonoid content (TFC) was evaluated according to the method described by Kivrak et al. (29). Quercetin was used as a standard in the linear range of 5-80 μg/mL (R2=0.9972) and the results were expressed in μg quercetin equivalents (QE) per g of dry mass.

Determination of antioxidant activity

The ability of the extracts to donate an electron and scavenge 2,2-diphenil-1-picrylhydrazyl (DPPH) radical was determined by the slightly modified method of Brand-Williams et al. (30) as described by Mihaylova et al. (31). The radical scavenging activity of the extracts against 2,2´-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid) (ABTS•+) was estimated according to Re et al. (32). The Fe3+ reducing antioxidant power (FRAP) assay was carried out according to a slightly modified procedure of Benzie and Strain (33). Prior to use, the freshly prepared FRAP reagent was warmed to 37 °C. The extracts were allowed to react with 2.85 mL of the FRAP reagent for 4 min at 37 °C, and the absorbance was measured at 593 nm. The Cu2+ reducing antioxidant capacity (CUPRAC) assay, which enables the total antioxidant capacity measurements of hydrophilic as well as hydrophobic samples. was carried out according to the procedure of Apak et al. (34).

Water activity and microbial count

The water activity and microbial load of the samples were measured as described by Mihaylova et al. (35).

Microscopic imaging

The photographs of the pores of the muffins were obtained via a USB Digital pocket microscope MX200-B (T TAKMLY, Shenzhen Huishixin Technology Co Ltd, Shenzhen, PR China) with 1000× LED magnification endoscope camera and a focus range of 1-9 mm. ImageJ software (36) was used to calculate the size of the pores.

Sensory evaluation

Sensory analysis was performed at the University of Food Technologies, Plovdiv, Bulgaria. The evaluation followed the description of Mihaylova et al. (37). Attributes of the evaluation were appearance (N=8), aroma (N=5), taste (N=6), mouthfeel (N=8) and aftertaste (N=7).

Statistical analysis

Data were analyzed using MS Excel software (38). All assays were performed in at least three repetitions. Results were presented as mean value±standard deviation (S.D.). Relevant statistical analyses of the data were performed using one-way ANOVA and a Tukey-Kramer post hoc test (α=0.05), as described by Assaad et al. (39).

RESULTS AND DISCUSSION

In order to accurately compare the newly developed formulations, several parameters were considered, i.e. moisture and ash content, nutritional data, crust and crumb colour, texture analysis, pore distribution, TPC, TFC, antioxidant activity, browning index, water activity and sensory evaluation.

Table 1 shows the physical properties and nutritional data of the muffin formulations. The control sample was characterised with the highest volume and height, and with the addition of chia seeds and peach powder these parameters decreased. Other authors have found similar results with the addition of ingredients like grape pomace (40), cocoa fibre (41) and kimchi powder (20).

Table 1 Physical characteristics, ash, moisture, water activity, microbial load and nutritional data of muffins
SampleControlF1F2
h/cm(7.2±1.0)a(5.3±0.1)b(5.4±0.3)b
m/g(36.3±5.1)b(61.1±3.9)a(51.6±7.8)a
Loss rate/%(11.6±1.6)a(3.2±1.4)b(3.63±0.9b
V/cm3(21.2±0.3)a(9.1±0.8)b(10.5±1.5)b
w(ash)/%(1.1±0.2)a(1.5±0.3)a(1.00±0.07)a
w(moisture)/%(20.2±0.6)c(35.2±1.3)a(30.6±2.8)b
aw(0.760±0.001)c(0.89±0.01)a(0.84±0.01)b
t(testing)/h048960489604896
N(AMM)/(CFU/g)2·1013·1023.5·1024·1011023.2·1023·1011.5·1023·102
N(YM)/(CFU/g)2.2·102<10<10103<10<101.5·103<10<10
w(protein)/(g/100 g)8.794.043.71
w(carbohydrate)/(g/100 g)49.3223.4723.27
w(sugar)/(g/100 g)27.364.905.04
w(fibre)/(g/100 g)04.254.24
w(fat)/(g/100 g)5.71.821.82
w(saturated fat)/(g/100 g)1.480.130.13
E/kcal276.98123.51121.92

Different letters in superscript in the same row indicate statistically significant differences (p<0.05), according to one-way ANOVA and the Tukey’s test. F1 and F2=formulations containing sugar, water, baking powder, chia seeds, einkorn flour at 30 and 27 %, and peach powder at 3 and 6 %, respectively, AMM=aerobic mesophilic microorganisms, YM=yeasts and mould, CFU=colony forming units

The mass of the reformulated muffins increased and the baking loss decreased. These findings correspond well to other papers concerning newly developed muffin formulations (20,23). Since the final volume is particularly important for bakery products, it has to be noted that other researchers have documented similar results, which are most likely due to the presence of dietary fibre and the dilution of gluten (42).

Information about the carbohydrate, protein and fat content is introduced inTable 1. The new formulations are characterised with reduced sugar and carbohydrate mass fraction compared to the control sample. Between the two formulations (F1 and F2), it can be seen that they bear very similar nutritional values. Muffins, in general, are characterised with an increased fat and sugar amount, thus reformulation in this direction is important not only because of the rising obesity worldwide, but also because products with a target nutritional profile and consumer acceptability may aid in reducing obesity rates (43). Following the Regulation (EC) No 1924/2006 (44) of the European Parliament and of the Council of 20 December 2006 on nutrition and health claims made on foods, the newly developed formulations are sources of fibre since they provide 4.24 g/100 g in formulation F2 and 4.25 g/100 g in formulation F1. Expectedly, the dietary fibre mass fraction increased with the incorporation of chia seeds.

Determining the moisture and ash mass fraction as well as the nutritional data of the end product is important. The moisture mass fraction of the control and the newly formulated ones varied from (20.23±0.61) to (35.15±1.28) %. The lowest values were established in the control sample, indicating that the absence of eggs and their substitution with chia seeds in formulations F1 and F2 led to a more moist product, which is rather untypical for baked samples. Other papers document 21.71 to 23.90 % moisture in muffins formulated with kimchi by-product powder (20), which is similar to the control sample of the current study. The ash mass fraction was in the range from 1 to 1.53 %. The highest values were established in formulation F1. Considering the ash mass fraction, other papers show similar values (20).

The aw of the formulations was evaluated and the results varied from 0.760±0.001 in the control sample to 0.89±0.01 in F1, which had the highest moisture content (Table 1). These results are lower than the ones documented by Struck et al. (45) about fibre-enriched sugar-reduced muffins where the water activity ranged from 0.85 to 0.98. However, F1 had more water available for reactions and microorganisms to use. The aw recorded for F2 was 0.8±0.01. The results correspond well to the established moisture content in the muffin formulations. The recorded microbial load at 0, 48 and 96 h of storage showed that the muffin formulations are safe for consumption. The percentage of added peach powder did not significantly influence the total count of yeast, mould and aerobic mesophilic microorganisms (AMM). The established aw values correspond well to the AMM count.

Fig. 1 shows cross sections of horizontally cut muffins as well as micrographs of the pores of all studied samples. It can be easily seen that the inclusion of chia seeds and peach powder has led to a decreased air cell formation.

Fig. 1 Photographs and micrographs of muffin pores: a) control sample, b) sample F1, and c) sample F2. F1 and F2=formulations containing sugar, water, baking powder, chia seeds, einkorn flour at 30 and 27 %, and peach powder at 3 and 6 %, respectively
FTB-61-273-f1

The control sample contained small and uniform air pockets, while F1 and F2 had irregular ones, and tunnel-like areas. This describes the same trend as observed by other researchers who studied reformulated muffins (20). Control sample had the smallest pores ((1.4±0.6) mm), while F1 and F2 had pores in the range from (3.19±1.08) to (3.80±0.63) mm.

Texture attributes represented by hardness, gumminess, chewiness, springiness and cohesiveness, as well as crust and crumb colour of the formulations described with L*, a*, b*, C and h values, are presented inTable 2. Both texture and colour characteristics can affect the perception of a food product and its overall acceptance.

Table 2 Colour characteristics (L*, a*, b*, C and h), browning index, and texture attributes of the muffins
SampleL*a*b*ChBI
Crust
Control(74.8±1.8)a(9.5±0.9)d(32.3±0.6)b(33.7±0.7)b(73.7±1.4)a(13.2±1.2)c
F1(29.5±3.6)a(13.4±1.3)e(18.7±0.6)d(23.1±0.9)d(54.5±2.8)b(36.9±3.7)c
F2(34.5±2.6)b(15.3±0.8)e(19.7±1.6)d(25.0±1.7)c(52.1±1.1)a(35.2±1.9)b
Crumb
Control(75.7±1.2)b(1.1±0.2)e(17.6±0.8)c(17.6±0.8)c(86.3±0.5)a(3.3±0.2)d
F1(39.3±1.9)b(8.4±0.2)e(17.1±0.9)d(19.3±0.9)c(54.3±1.1)a(19.4±1.0)c
F2(40.9±1.9)b(8.1±0.3)d(19.1±1.5)c(20.8±1.3)c(66.9±1.7)a(18.4±1.0)c
Texture profile
Hardness/N
Cycle 1
Gumminess/NAdhesiveness/(N/mm2)Springiness/mmCohesivenessChewiness/J
Cycle 2
Control10537±16(6427±416)c(0.6±0.02)c(3.5±0.1)b(0.6±0.03)c(22573±1882)c
8235±14
F17267±25(23692±1135)b(5.2±0.2)b(2.7±0.3)c(3.3±0.2)b(62932±5431)b
6486±30
F212325±20(53334±3844)a(6.8±0.1)a(4.2±0.3)a(4.2±0.3)a(164156±79357)a
10347±30

Different letters in superscript in the same column indicate statistically significant differences (p<0.05), according to one-way ANOVA and the Tukey’s test. F1 and F2=formulations containing sugar, water, baking powder, chia seeds, einkorn flour at 30 and 27 %, and peach powder at 3 and 6 %, respectively, BI=browning index

The results reveal that the control sample is harder than F1 but less hard than F2. This tendency is similar to the one reported by Najjar et al. (46) concerning the texture profile of cookies formulated with date seed powder. The absence of eggs resulted in increased values in the adhesiveness and cohesiveness parameters. Lower cohesiveness is associated with increased crumbliness due to greater hardness (40). This thesis is further supported by the sensory evaluation of the muffin formulations presented later in this research. Moreover, in sample F1, the springiness was the lowest (2.66 mm). Springiness is an important mechanical feature associated with an elastic and fresh aerated product (47). The adhesiveness and cohesiveness were highly influenced by the recipe alteration. Egg white protein aids in the air and volume formation. Its absence leads to products with smaller volume, which is visible in the formulations with chia seeds. This is most likely because of the increased density and reduced number of air pockets. Chewiness reflects the difficulty needed to chew food and form bolus prior to swallowing (48). The formulated samples require additional force to chew them and there is a proportional reference between the mass fraction of added peach powder and the chewiness values.

The newly developed formulations appeared darker than the control. The difference in colour is due to the initial colour of the ingredients. Moreover, the presence of chia seeds and einkorn flour resulted in lighter inner part, with 15 % higher L* and h values. The crust of formulations F1 and F2 appeared darker, with higher a* and lower b* values, than of control sample. The F1 and F2 samples may appear the same to some consumers as they lean to the brown shade with weak hints of the yellow and red. The two new formulations had similarities in the colour perception, while the control sample was significantly different in its crust and crumb colour parameters. The calculated ∆E of the crust of F1 (47.46) and F2 (42.60) shows that the human eye perceives a difference between samples, but the newly developed samples are more similar in colour than different. The colour parameters are difficult to compare to other products because of the differences between recipe designs.

The values of the browning index were significantly different compared to the control sample and relatively similar for the newly formulated muffins (Table 2). The same trend was followed for both crumb and crust. The current results support the thesis of Shevkani and Singh (49) who state that the browning index very much depends on the initial ingredient colour of the product.

The TPC, expressed in GAE on dry mass basis, of the control sample was (0.06±0.00) mg/g. A fourfold increase was observed for the two new formulations, resulting in (0.25±0.01) (F1) and (0.32±0.00) mg/g (F2). Similarly, an increase in TPC was observed in muffins prepared with wheatgrass powder, with a 1.4-fold increase compared to the control sample (21). The TFC value of the control sample, expressed as QE on a dry mass basis, was zero, which is consistent with its ingredients. The F1 and F2, on the other hand, had (18.7±0.8) and (31.2±0.4) μg/g, respectively. Similar results were reported for muffins fortified with capsicum pomace powder (50).

The addition of peach powder and chia seeds, as well as flour substitution led to a significant increase in the antioxidant activity measured by four contemporary methods (Fig. 2). Other authors also found the increase in their samples (21,22) based on their ingredients i.e. sunflower flour and wheatgrass powder.

Fig. 2 Antioxidant activity of muffin formulations measured on dry mass basis by ABTS (mM/g), DPPH (µM/g), FRAP (µM/g) and CUPRAC (µM/g) assays. Different letters in the same assay indicate statistically significant differences (p<0.05), according to one-way ANOVA and the Tukey’s test. F1 and F2=formulations containing sugar, water, baking powder, chia seeds, einkorn flour at 30 and 27 %, and peach powder at 3 and 6 %, respectively
FTB-61-273-f2

The highest values were measured by the ABTS assay. Formulations F1 and F2 had similar results, which is in accordance with their TPC. Some authors state that a higher natural antioxidant content can have a positive influence of the shelf life of baked goods (51). Here, the addition of chia seeds and peach powder increased the overall bioactive profile of the muffins. Similarly, studies have shown that levels of FRAP increase 2.9-fold in in muffins prepared with sunflower flour (22).

The evaluation of sensory properties of the muffins is presented inTable 3. In terms of appearance, the muffins had distinct differences. The colour of the control sample was yellowish, while the two other formulations were described as golden brown. All samples were considered uniform in colour. Formulations F1 and F2 left a sticky feeling on the fingers and had an uneven surface top. The control sample, on the other hand, was marked with an even top surface, but very crumbly when pulled apart.

Table 3 Sensory evaluation of muffin formulations
Attribute/sampleControlF1F2
Appearance
yellow colour(12.3±1.9)a(1.0±0.7)b(0.9±0.6)b
golden brown colour(0.0±0.0)b(12.7±0.9)a(13.3±1.2)a
variation of pore size(3.5±1.6)b(11.9±1.2)a(12.6±1.2)a
sticky to touch(4.7±1.0)b(13.5±0.8)a(13.8±0.9)a
dry to touch(10.6±1.7)a(1.7±0.8)b(2.0±0.8)b
crumbly when pulled apart(12.4±1.3)a(2.6±1.4)b(3.7±1.3)b
uneven top surface(1.7±0.8)b(10.6±1.6)a(11.2±1.3)a
uniformity of colour (13.4±1.4)a(12.4±1.1)a(12.2±1.0)a
Aroma
sweet(9.7±1.9)b(13.4±1.05(13.1±1.2)a
egg-like(9.3±0.7)a(0.3±0.48)b(0.3±0.5)b
pumpkin-like(0.0±0.0)c(9.8±1.3)b(11.4±1.8)a
fruity(0.0±0.0)b(4.7±2.0)a(5.8±1.6)a
caramel-like(0.9±0.6)b(3.9±1.7)a(3.8±1.8)a
Taste
sweet(14.2±0.8)a(12.2±0.9)b(12.3±1.0)b
egg-like(9.3±1.5)a(0.0±0.0)b(0.00±0.00)b
fruity(2.3±1.2)b(4.7±1.9)a(5.6±1.0)a
flour-like(6.1±1.2)a(3.5±1.3)b(3.5±1.6)b
insipid (flavourless)(0.6±0.5)b(0.2±0.4)b(1.6±1.0)a
bitter(0.8±0.6)a(1.9±1.6)a(1.6±1.0)a
Mouthfeel
crunchy(1.4±0.5)b(6.0±0.8)a(5.1±1.4)a
tooth packing(5.4±1.3)a(6.3±1.6)a(5.7±1.5)a
tongue film-forming(6.1±1.2)a(4.8±1.3)a(5.0±1.2)a
salivating(7.1±1.2)b(8.9±1.2)a(8.9±1.0)a
dry(8.9±1.0)a(3.2±1.3)b(3.3±1.9)b
sticky(5.4±1.4)b(8.9±0.7)a(8.7±0.9)a
difficult to bite(2.7±1.5)a(2.2±0.8)a(2.7±1.2)a
soft(8.5±1.6)a(7.9±1.1)a(7.6±1.4)a
Aftertaste
sweet(12.2±1.2)a(11.1±1.2)a(12.3±1.2)a
egg-like(5.1±1.9)a(0.0±0.0)b(0.0±0.0)b
dry(3.3±1.5)a(1.7±0.8)b(2.0±0.8)b
salivating(5.1±1.2)a(3.5±1.1)b(3.1±1.5)b
flour-like(2.1±1.0)a(1.7±0.9)a(2.5±1.1)a
fruity(0.0±0.0)b(3.5±1.1)a(3.7±1.5)a
bitter(1.3±0.7)a(1.5±0.8)a(2.0±1.0)a

Different letters in the same row indicate statistically significant differences (p<0.05) according to one-way ANOVA and the Tukey’s test. F1 and F2=formulations containing sugar, water, baking powder, chia seeds, einkorn flour at 30 and 27 %, and peach powder at 3 and 6 %, respectively

The inside of the muffins had different pore size and distribution. The control sample had the smallest pores, while F1 and F2 had bigger, unevenly distributed pores. This is in accordance with the findings discussed inFig. 1. The aroma was predominantly egg-like and sweet for the control sample, and pumpkin-like and sweet for F1 and F2. When tasting the samples, the panellists marked the sweet taste as predominant. Formulations F1 and F2 were also described as pleasantly crunchy, but forming a bolus in the mouth. The control sample on the other hand was dry and falling apart. The aftertaste of all muffin formulations was the sweet one. Since all formulations were well accepted by the panel, it can be concluded that the presence of 3 and 6 % of peach powder is acceptable. The absence of eggs, even though it led to differences in the surface top, was also accepted and the texture of the chia seeds in the ready product was not unpleasant.

The Pearson’s correlation coefficients between water activity, moisture mass fraction, antioxidant activity, TPC, TFC, browning index and CIELAB crust colour characteristics of muffin formulations are plotted inTable 4. All variables have a positive correlation, and the samples were considered to have a very high correlation, with a coefficient ≥0.75. A high degree of correlation is marked when 0.74≤R2≥0.50, while moderate degree of correlation is when the value lies between ±0.30 and ±0.49.

Table 4 Pearson’s correlation coefficients (R2) between water activity, moisture content, antioxidant activity (DPPH, ABTS, FRAP and CUPRAC assays), total phenolic content, total flavonoid content, browning index and CIELAB crust colour characteristics of muffin formulations
Control sampleBIL*a*b*ChWAMCTPCTFCDPPHABTSFRAPCUPRAC
BI10.9970.9980.6390.8390.9670.4790.4640.3120.9430.4460.9550.6210.097
L*0.997110.5810.7940.9850.5380.5230.3680.9130.3880.9280.6770.134
a*0.998110.5960.8060.9810.5230.5090.3540.9210.4020.9350.6640.124
b*0.6390.5810.59610.9470.4580.0140.0110.0030.8450.9630.8250.0670.104
C0.8390.7940.8060.94710.6860.1190.110.0320.9710.8280.9610.2260.009
h0.9670.9850.9810.4580.68610.6590.6450.490.8310.2720.8510.7860.229
WA0.4790.5380.5230.0140.1190.659110.9710.250.0060.2740.980.812
MC0.4640.5230.5090.0110.110.645110.9760.2380.0080.2610.9750.823
TPC0.3120.3680.3540.0030.0320.490.9710.97610.1190.060.1370.9040.925
TFC0.9430.9130.9210.8450.9710.8310.250.2380.11910.6820.9990.3830.006
DPPH0.4460.3880.4020.9630.8280.2720.0060.0080.060.68210.6560.0050.25
ABTS0.9550.9280.9350.8250.9610.8510.2740.2610.1370.9990.65610.410.01
FRAP0.6210.6770.6640.0670.2260.7860.980.9750.9040.3830.0050.4110.689
CUPRAC0.0970.1340.1240.1040.0090.2290.8120.8230.9250.0060.250.010.6891
F1BIL*a*b*chawmTPCTFCDPPHABTSFRAPCUPRAC
BI10.4510.9670.7390.9970.930.0020.7270.8430.9220.0330.3630.2160.784
L*0.45110.2770.9130.3940.2040.5890.0350.1040.1910.7240.9920.1180.882
a*0.9670.27710.5670.9850.9930.020.8710.950.9900.2010.3810.619
b*0.7390.9130.56710.6870.4820.2970.2180.3450.4660.4340.8560.0030.997
C0.9970.3940.9850.68710.95600.7770.8820.950.0160.3080.2650.735
h0.930.2040.9930.4820.95610.0510.9230.98110.0070.1370.4660.534
WA0.0020.5890.020.29700.05110.2380.1290.0580.980.6750.750.25
MC0.7270.0350.8710.2180.7770.9230.23810.980.9310.1280.0090.7380.262
TPC0.8430.1040.950.3450.8820.9810.1290.9810.9850.0490.0560.6050.395
TFC0.9220.1910.990.4660.9510.0580.9310.98510.010.1260.4820.518
DPPH0.0330.72400.4340.0160.0070.980.1280.0490.0110.8010.6170.383
ABTS0.3630.9920.2010.8560.3080.1370.6750.0090.0560.1260.80110.1820.818
FRAP0.2160.1180.3810.0030.2650.4660.750.7380.6050.4820.6170.18210
CUPRAC0.7840.8820.6190.9970.7350.5340.250.2620.3950.5180.3830.81801
F2BIL*a*b*chawmTPCTFCDPPHABTSFRAPCUPRAC
BI10.5540.2470.0020.0320.2770.4980.6160.0490.5310.2170.1790.9480.468
L*0.55410.0440.3970.2740.9210.0030.9960.2360.0070.060.0840.3280.993
a*0.2470.04410.7940.8890.2270.9320.0220.9150.9140.9990.9930.4640.086
b*0.0020.3970.79410.9830.6780.5510.3360.970.5180.8230.8570.0760.483
C0.0320.2740.8890.98310.5510.6780.220.9980.6460.910.9350.1590.354
h0.2770.9210.2270.6780.55110.0530.8840.5070.0390.2570.30.1020.961
WA0.4980.0030.9320.5510.6780.05310.0130.7180.9990.9130.8850.720.001
MC0.6160.9960.0220.3360.220.8840.01310.1850.0220.0330.0520.3890.978
TPC0.0490.2360.9150.970.9980.5070.7180.18510.6870.9340.9550.1920.313
TFC0.5310.0070.9140.5180.6460.0390.9990.0220.68710.8930.8630.7490
DPPH0.2170.060.9990.8230.910.2570.9130.0330.9340.89310.9980.4290.107
ABTS0.1790.0840.9930.8570.9350.30.8850.0520.9550.8630.99810.3820.138
FRAP0.9480.3280.4640.0760.1590.1020.720.3890.1920.7490.4290.38210.25
CUPRAC0.4680.9930.0860.4830.3540.9610.0010.9780.31300.1070.1380.251

MC=moisture content, BI=browning index, L, a, b, C, h=CIELAB parameters, WA=water activity, TPC=total phenolic content, TFC=total flavonoid content, F1 and F2=formulations containing sugar, water, baking powder, chia seeds, einkorn flour at 30 and 27 %, and peach powder at 3 and 6 %, respectively

It can be seen that a very limited number of statistically independent variables, with a correlation coefficient equal to zero, exists in this study. The antioxidant activity, TPC and TFC are very commonly correlated in research papers (52). The R2 values indicate that the phenolic and flavonoid compounds are contributors to the antioxidant activity in all muffin formulations at different levels. Good correlation coefficients were established considering the colour characteristics and the TPC, TFC and antioxidant activity. Other papers have also determined a correlation between colorimetric values and TPC and TFC (53).

CONCLUSIONS

Muffins are generally very well accepted by consumers and are often chosen as a dessert or snack throughout the day. Faced with increased calorie intake and unhealthy eating habits, the consumer demands healthier alternatives of desired goods. Thus, the impact of the inclusion of peach powder, einkorn wheat, and chia seeds as egg substituent in muffins was studied. Reformulation led to a product with less energy, sugars and fat, as well as an increased fibre content and antioxidant activity, in line with the current trend for foods with enhanced functional properties. The newly developed products showed good results in terms of quality and based on the comparison of the studied parameters with the control sample. The colour of the newly developed muffin formulations was significantly different from the control sample, mostly due by the ingredients (flour type, chia seeds). The micrographs showed pores with increased size and the sensory evaluation pointed out a distinct stickiness in the formulated muffins. However, both new formulations were generally well-accepted by the panellists. The results of this study indicate that a potential for the formulations of muffins with chia seeds and lyophilized peach powder exists without deteriorating important quality attributes. Future reformulation could target the sugar (total substitution) and protein (increase) content of the muffins.

ACKNOWLEDGEMENTS

The authors would like to express their gratitude to Prof. Argir Zhivondov from the Fruit Growing Institute, Plovdiv, Bulgaria, and his team for kindly providing the peach variety ’Evmolpiya’ used to prepare the formulations.

Notes

[1] Financial disclosure FUNDING

This work was supported by the Bulgarian National Science Fund, project no. KП-06-H37/23.

[2] Conflicts of interest CONFLICT OF INTEREST

Authors declare no conflict of interest.

SUPPLEMENTARY MATERIALS

Supplementary materials are available at:www.ftb.com.hr.

REFERENCES

1 

Healthy diet. Cairo, Egypt: World Health Organization (WHO) Regional Office for the Eastern Mediterranean; 2019. Available from:https://apps.who.int/iris/bitstream/handle/10665/325828/EMROPUB_2019_en_23536.pdf.

2 

Ruikka J. The Western diet's negative impact on the health of the Pacific Islands [BSc Thesis]. Louisville, KY, USA: University of Louisville; 2016. https://doi.org/10.18297/honors/99 https://doi.org/10.18297/honors/99

3 

Pretorius B, Ambuko J, Papargyropoulou E, Schönfeldt HC. Guiding nutritious food choices and diets along food systems. Sustainability. 2021;13:9501. https://doi.org/10.3390/su13179501

4 

Luo X, Arcot J, Gill T, Louie JCY, Rangan A. A review of food reformulation of baked products to reduce added sugar intake. Trends Food Sci Technol. 2019;86:412–25. https://doi.org/10.1016/j.tifs.2019.02.051

5 

Ozuna C, Trueba-Vázquez E, Moraga G, Llorca E, Hernando I. Agave syrup as an alternative to sucrose in muffins: Impacts on rheological, microstructural, physical, and sensorial properties. Foods. 2020;9(7):895. https://doi.org/10.3390/foods9070895 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/32650358

6 

Agha M, Agha R. The rising prevalence of obesity: Part A: Impact on public health. Int J Surg Oncol. 2017;2(7):e17. https://doi.org/10.1097/IJ9.0000000000000017 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/29177227

7 

Gorski MT, Roberto CA. Public health policies to encourage healthy eating habits: Recent perspectives. J Healthc Leadersh. 2015;7:81–90. https://doi.org/10.2147/JHL.S69188 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/29355201

8 

Chaudhary A, Sudzina F, Mikkelsen BE. Promoting healthy eating among young people - A review of the evidence of the impact of school-based interventions. Nutrients. 2020;12(9):2894. https://doi.org/10.3390/nu12092894 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/32971883

9 

Katunzi-Kilewela A, Kaale L, Kibazohi O, Rweyemamu L. Nutritional, health benefits and usage of chia seeds (Salvia hispanica): A review. Afr J Food Sci. 2021;15(2):48–59. https://doi.org/10.5897/AJFS2020.2015

10 

Jerez S, Medina A, Alarcón G, Sierra L, Medina M. Chia seed oil intake: Is it beneficial for preventing cardiovascular risk factors? Biol Life Sci Forum. 2021;8:7. https://doi.org/10.3390/blsf2021008007

11 

Scapin G, Schmidt MM, Prestes RC, Rosa CS. Phenolics compounds, flavonoids and antioxidant activity of chia seed extracts (Salvia hispanica) obtained by different extraction conditions. Int Food Res J. 2016;23(6):2341–6.

12 

Gazem R, Puneeth H, Madhu C, Sharada A. Physicochemical properties and in vitro anti-inflammatory effects of Indian chia (Salvia hispanica L.) seed oil. J Pharm Biol Sci. 2016;11(2):1–8. https://doi.org/10.9790/3008-1102040108

13 

Silva LA, Verneque B, Mota A, Duarte C. Chia seed (Salvia hispanica L.) consumption and lipid profile: A systematic review and meta-analysis. Food Funct. 2021;12:8835–49. https://doi.org/10.1039/D1FO01287H PubMed: http://www.ncbi.nlm.nih.gov/pubmed/34378609

14 

Ye EQ, Chacko SA, Chou EL, Kugizaki M, Liu S. Greater whole-grain intake is associated with lower risk of type 2 diabetes, cardiovascular disease, and weight gain. J Nutr. 2012;142(7):1304–13. https://doi.org/10.3945/jn.113.179473 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/22649266

15 

Antognoni F, Mandrioli R, Bordoni A, Di Nunzio M, Viadel B, Gallego E, et al. Integrated evaluation of the potential health benefits of einkorn-based breads. Nutrients. 2017;9(11):1232. https://doi.org/10.3390/nu9111232 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/29137113

16 

Tighe-Neira R, Alberdi M, Arce-Johnson P, Romero-Romero JL, Reyes-Díaz M, Inostroza-Blancheteau C. Foods with functional properties and their potential uses in human health. In: Waisundara v, Shiomi N, editors. Superfood and functional food - An overview of their processing and utilization. London, UK: IntechOpen; 2017. https://doi.org/10.5772/67077 https://doi.org/10.5772/67077

17 

Oliveira A, Amaro AL, Pintado M. Impact of food matrix components on nutritional and functional properties of fruit-based products. Curr Opin Food Sci. 2018;22:153–9. https://doi.org/10.1016/j.cofs.2018.04.002

18 

Ullah H, De Filippis A, Khan H, Xiao J, Daglia M. An overview of the health benefits of Prunus species with special reference to metabolic syndrome risk factors. Food Chem Toxicol. 2020;144:111574. https://doi.org/10.1016/j.fct.2020.111574 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/32679287

19 

de Souza EC, Cordeiro DA, Silva BS, Neves N, Schmiele M. Development of muffin with the incorporation of olive pomace flour, extra virgin olive oil and hydrolyzed soy protein. Res Soc Dev. 2022;11(2):e58511226012. https://doi.org/10.33448/rsd-v11i2.26012

20 

Heo Y, Kim MJ, Lee JW, Moon B. Muffins enriched with dietary fiber from kimchi by-product: Baking properties, physical–chemical properties, and consumer acceptance. Food Sci Nutr. 2019;7(5):1778–85. https://doi.org/10.1002/fsn3.1020 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/31139391

21 

Rahman R, Hiregoudar S, Veeranagouda M, Ramachandra CT, Nidoni U, Roopa RS, et al. Effects of wheat grass powder incorporation on physiochemical properties of muffins. Int J Food Prop. 2015;18(4):785–95. https://doi.org/10.1080/10942912.2014.908389

22 

Grasso S, Pintado T, Pérez-Jiménez J, Ruiz-Capillas C, Herrero AM. Characterisation of muffins with upcycled sunflower flour. Foods. 2021;10(2):426. https://doi.org/10.3390/foods10020426 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/33672080

23 

Harastani R, James LJ, Ghosh S, Rosenthal AJ, Woolley E. Reformulation of muffins using inulin and green banana flour: physical, sensory, nutritional and shelf-life properties. Foods. 2021;10(8):1883. https://doi.org/10.3390/foods10081883 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/34441660

24 

Official Method AOAC. 945.46. Ash of milk, Gravimetric method. Rockville, MD, USA: AOAC international; 1945.

25 

Method AACC. 44-15.02. Moisture - Air-oven methods. St. Paul, MN, USA: Cereals & Grains Association; 2010.

26 

Mihaylova D, Popova A, Desseva I, Manolov I, Petkova N, Vrancheva R, et al. Comprehensive evaluation of late season peach varieties (Prunus persica L.): Fruit nutritional quality and phytochemicals. Molecules. 2021;26(9):2818. https://doi.org/10.3390/molecules26092818 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/34068685

27 

Method AACC. 74-09. Measurement of bread firmness by universal testing machine. St. Paul, MN, USA: Cereals & Grains Association; 1999.

28 

Kujala TS, Loponen JM, Klika KD, Pihlaja K. Phenolics and betacyanins in red beetroot (Beta vulgaris) root: Distribution and effect of cold storage on the content of total phenolics and three individual compounds. J Agric Food Chem. 2000;48:5338–42. https://doi.org/10.1021/jf000523q PubMed: http://www.ncbi.nlm.nih.gov/pubmed/11087483

29 

Kivrak İ, Duru ME, Öztürk M, Mercan N, Harmandar M, Topçu G. Antioxidant, anticholinesterase and antimicrobial constituents from the essential oil and ethanol extract of Salvia potentillifolia. Food Chem. 2009;116:470–9. https://doi.org/10.1016/j.foodchem.2009.02.069

30 

Brand-Williams W, Cuvelier ME, Berset C. Use of a free radical method to evaluate antioxidant activity. Lebensm Wiss Technol. 1995;28:25–30. https://doi.org/10.1016/S0023-6438(95)80008-5

31 

Mihaylova D, Lante A, Krastanov A. Total phenolic content, antioxidant and antimicrobial activity of Haberlea rhodopensis extracts obtained by pressurized liquid extraction. Acta Aliment. 2015;44:326–32. https://doi.org/10.1556/AAlim.2014.0009

32 

Re R, Pellegrini N, Proteggente A, Pannala A, Yang M, Rice-Evans C. Antioxidant activity applying an improved ABTS radical cation decolorization assay. Free Radic Biol Med. 1999;26:1231–7. https://doi.org/10.1016/S0891-5849(98)00315-3 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/10381194

33 

Benzie IFF, Strain JJ. Ferric reducing/antioxidant power assay: direct measure of total antioxidant activity of biological fluids and modified version for simultaneous measurement of total antioxidant power and ascorbic acid concentration. Methods Enzymol. 1999;299:15–27. https://doi.org/10.1016/S0076-6879(99)99005-5 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/9916193

34 

Apak R, Güçlü K, Özyürek M, Karademir SE. Novel total antioxidant capacity index for dietary polyphenols and vitamins C and E, using their cupric ion reducing capability in the presence of neocuproine: CUPRAC method. J Agric Food Chem. 2004;52:7970–81. https://doi.org/10.1021/jf048741x PubMed: http://www.ncbi.nlm.nih.gov/pubmed/15612784

35 

Mihaylova D, Popova A, Goranova Z, Doykina P. Development of healthy vegan bonbons enriched with lyophilized peach powder. Foods. 2022;11(11):1580. https://doi.org/10.3390/foods11111580 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/35681330

36 

Rueden CT, Schindelin J, Hiner MC, DeZonia BE, Walter AE, Arena ET, et al. ImageJ2: ImageJ for the next generation of scientific image data. BMC Bioinformatics. 2017;18:529. https://doi.org/10.1186/s12859-017-1934-z PubMed: http://www.ncbi.nlm.nih.gov/pubmed/29187165

37 

Mihaylova D, Popova A, Goranova Z, Petkova D, Doykina P, Lante A. The perspective of nectarine fruit as a sugar substituent in puddings prepared with corn and rice starch. Foods. 2021;10(11):2563. https://doi.org/10.3390/foods10112563 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/34828844

38 

Excel M. Microsoft Corporation, Redmond, WA, USA; 2021. Available from:https://office.microsoft.com/excel.

39 

Assaad HI, Zhou L, Carroll RJ, Wu G. -ready MS-word tables for one-way ANOVA. Springerplus. 2014;3:474.; Rapid publication https://doi.org/10.1186/2193-1801-3-474 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/25191639

40 

Walker R, Tseng A, Cavender G, Ross A, Zhao Y. Physicochemical, nutritional, and sensory qualities of wine grape pomace fortified baked goods. J Food Sci. 2014;79:S1811–22. https://doi.org/10.1111/1750-3841.12554 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/25102950

41 

Martínez-Cervera S, Salvador A, Muguerza B, Moulay L, Fiszman SM. Cocoa fibre and its application as a fat replacer in chocolate muffins. Lebensm Wiss Technol. 2011;44(3):729–36. https://doi.org/10.1016/j.lwt.2010.06.035

42 

Bagheri R, Seyedein SM. The effect of adding rice bran fibre on wheat dough performance and bread quality. World Appl Sci J. 2011;14:121–5.

43 

Harastani R, James L, Walton J, Woolley E. Tackling obesity: A knowledge-base to enable industrial food reformulation. Innov Food Sci Emerg. 2020;64:102433. https://doi.org/10.1016/j.ifset.2020.102433

44 

Regulation (EC) No. 1924/2006 of the European Parliament and of the Council of 20 December 2006 on nutrition and health claims made on foods. OJ L. 2006;404:9–25.

45 

Struck S, Gundel L, Zahn S, Rohm H. Fiber enriched reduced sugar muffins made from iso-viscous batters. Lebensm Wiss Technol. 2016;65:32–8. https://doi.org/10.1016/j.lwt.2015.07.053

46 

Najjar Z, Alkaabi M, Alketbi K, Stathopoulos C, Ranasinghe M. Physical chemical and textural characteristics and sensory evaluation of cookies formulated with date seed powder. Foods. 2022;11(3):305. https://doi.org/10.3390/foods11030305 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/35159461

47 

Krishnaiya R, Kasar C, Gupta S. Influence of water chestnut (Trapa natans) on chemical, rheological, sensory and nutritional characteristics of muffins. J Food Meas Charact. 2015;10:210–9. https://doi.org/10.1007/s11694-015-9295-7

48 

Goswami D, Gupta RK, Mridula D, Sharma M, Tyagi SK. Barnyard millet based muffins: Physical, textural and sensory properties. Lebensm Wiss Technol. 2015;64(1):374–80. https://doi.org/10.1016/j.lwt.2015.05.060

49 

Shevkani K, Singh N. Influence of kidney bean, field pea and amaranth protein isolates on the characteristics of starch-based gluten-free muffins. Int J Food Sci Technol. 2014;49:2237–44. https://doi.org/10.1111/ijfs.12537

50 

Nath P, Kale S, Kaur C, Chauhan OP. Phytonutrient composition, antioxidant activity and acceptability of muffins incorporated with red capsicum pomace powder. J Food Sci Technol. 2018;55(6):2208–19. https://doi.org/10.1007/s13197-018-3138-6 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/29892122

51 

do Nascimento KDO, do Nascimento SDP, Augusta IM. A review ‘Clean Labeling’: Applications of natural ingredients in bakery products. J Food Nutr Res. 2018;6(5):285–94. https://doi.org/10.12691/jfnr-6-5-2

52 

Muflihah YM, Gollavelli G, Ling YC. Correlation study of antioxidant activity with phenolic and flavonoid compounds in 12 Indonesian indigenous herbs. Antioxidants. 2021;10(10):1530. https://doi.org/10.3390/antiox10101530 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/34679665

53 

Katırcı N, Güpür N, Guler H, Gursoy O, Yilmaz Y. Differences in antioxidant activity, total phenolic and flavonoid contents of commercial and homemade tomato pastes. J Saudi Soc Agric Sci. 2020;19(4):249–54. https://doi.org/10.1016/j.jssas.2018.11.003

Appendices

Table S1 Muffin formulations
IngredientControlw(ingredient)/%
F1
F2
Sugar262828
Wheat four3200
Einkorn flour03027
Eggs4200
Chia seeds044
Peach powder036
Water034.834.8
Baking powder00.20.2

F1 and F2=formulations containing sugar, water, baking powder, chia seeds, einkorn flour at 30 and 27 %, and peach powder at 3 and 6 %, respectively

Fig. S1 Muffin formulations: a) control sample, b) F1, and c) F2. F1 and F2=formulations containing sugar, water, baking powder, chia seeds, einkorn flour at 30 and 27 %, and peach powder at 3 and 6 %, respectively
FTB-61-273-fS1

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