Cistus extract as a valuable component for enriching wheat bread

Journal Pre-proof Cistus extract as a valuable component for enriching wheat bread Anna Mikulec, Stanisław Kowalski, Małgorzata Makarewicz, Łukasz Skoczylas, Małgorzata Tabaszewska PII:

S0023-6438(19)31055-2

DOI:

https://doi.org/10.1016/j.lwt.2019.108713

Reference:

YFSTL 108713

To appear in:

LWT - Food Science and Technology

Received Date: 21 March 2019 Revised Date:

4 October 2019

Accepted Date: 6 October 2019

Please cite this article as: Mikulec, A., Kowalski, Stanisł., Makarewicz, Mał., Skoczylas, Ł., Tabaszewska, Mał., Cistus extract as a valuable component for enriching wheat bread, LWT - Food Science and Technology (2019), doi: https://doi.org/10.1016/j.lwt.2019.108713. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Published by Elsevier Ltd.

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Cistus extract as a valuable component for enriching wheat bread

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Anna Mikulec1, Stanisław Kowalski2, Małgorzata Makarewicz3, Łukasz Skoczylas4,

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MałgorzataTabaszewska4

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1)

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[email protected]

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2)

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Agriculture in Krakow, ul. Balicka 122, 30-149 Krakow, Poland

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3)

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Technology, University of Agriculture in Krakow, ul. Balicka 122, 30-149 Krakow, Poland

State Higher Vocational School in Nowy Sacz, ul. Staszica 1, 33-300 Nowy Sacz, Poland,

Department of Carbohydrate Technology, Faculty of Food Technology, University of

Department of Fermentation Technology and Technical Microbiology, Faculty of Food

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4)

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Technology, University of Agriculture in Krakow, ul. Balicka 122, 30-149 Krakow, Poland

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Corresponding author:

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Anna Mikulec, e-mail: [email protected], ul. Staszica 1, 33-300 Nowy Sacz, Poland

Department of Technology of Fruits, Vegetables and Mushrooms, Faculty of Food

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Keywords: wheat-cistus bread, bread stalling index, polyphenol profile, microbiological

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properties of the crumb, crumb color

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Abstract. The aim of the study was to use cistus extract for the production of wheat bread and

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determine its impact on selected physicochemical, microbiological, and organoleptic

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characteristics, the color of the crumb, changes in the crumb texture, polyphenol profile and

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the total polyphenol content. Breads with 5 and 7.5% cistus extract were characterized by

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lower average scores for taste and smell, compared to wheat bread. During storage (up to 5

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days) the largest increase of crumb hardness was observed for wheat bread, as much as

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72.89%, compared to the first day of storage, in contrast to bread with 5 % cistus extract

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(29.03%). The replacement of water by cistus extract influenced the color of the crumb by

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increasing its browning index from 30.92 (standard bread) to 66.47 (7.5% cistus extract). The

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cistus extract contributed to an improvement of the microbiological quality of the bread. The

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addition of the cistus extract influenced the polyphenol content by increasing it from 8.88

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(wheat bread) to 78.71 mg/100 g (breads with 7.5 % cistus extract) and the total polyphenol

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content from 62.81 to 105.81 mg GAE per 100 g of product, compared to the wheat bread.

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1. INTRODUCTION

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Bread is a food product of great importance for consumers. It is still popular and consumed

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every day in many countries. The assortment of bakery products is constantly expanding with

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new products, often enriched with products of natural origin. For the enrichment of bread, and

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thus for a significant change not only of its organoleptic characteristics, but also of health-

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promoting properties, various additives are used, such as non-cereal grains, herbs, oilseeds

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and dried fruits and vegetables (Ibrahim, Salleh, & Maqsood-ul-Haque, 2015). From a

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nutritional point of view, cistus (Cistus incanus L.) is a valuable source of many antioxidant

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compounds including ellagic and gallic acids, terpenoids, flavonoids and tannins (Viapiana,

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Konopacka, Waleron, & Wesolowski, 2017). Cistus has strong anti-inflammatory properties

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(Benkhnigue, Hachi, Fadli, Douira, & Zidane, 2016; Küpeli, & Yesilada, 2007; Sayah et al.,

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2017) and, among others, antileukemic, antioxidant, antiperoxidant, antiradicular, antiseptic,

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antiulcer, astringent, bactericide, candidicide, cardioprotective, dermoprotective, fungicide,

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gastroprotective, hemostat, myorelaxant, nervine, purgative, revulsive, sedative, and

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spasmolytic properties (Duke, Duke, & duCellier, 2008). It was also found that the

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polyphenol compounds contained in cistus can inhibit the development of tumors,

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demonstrating cytotoxic activity (Barrajón-Catalán et al., 2010; Vitali, Pennisi, Attaguile,

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Savoca, & Tita, 2011). The beneficial effects of various species of cistus against pathogenic

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microorganisms, bacteria or fungi have also been proved (Tomás-Menor et al., 2013;

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Viapiana et al., 2017). In-vitro studies confirmed that the extract of cistus inhibits

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multiplication and reduces the population of the bacterium Borrelia burgdorferi, the

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etiological factor of borreliosis (Hutschenreuther, Birkemeyer, Grötzinger, Straubinger, &

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Rauwald, 2010) and inhibits human immunodeficiency virus (HIV) infections (Rebensburg et

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al., 2016). Kuchta et al. (2019) observed that use of Cistus incanus herbal tea on a daily basis

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can reduces cardiovascular risk factors including dyslipidemia and oxidative stress. Lisiecka,

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Wójtowicz, Dziki, Gawlik-Dziki (2019) enriched wheat pasta with the addition of Cistus

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incanus leaves and observed an increase in the total phenolic content (TPC) and the

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antioxidant activity of supplemented pasta. Cacak-Pietrzak et al. (2019) supplemented wheat

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bread with the addition of 1 up to 5 % of ground Cistus incanus and also observed

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significantly higher TPC and much higher antioxidant activity of bread with this herb’s

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leaves. To date, no research has been conducted to determine the effect of cistus extract on

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bread characteristics. Moreover, other authors used dried Cistus incanus leaves for the

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production of bread and pasta (Cacak-Pietrzak et al., 2019; Lisiecka et al., 2019), which could

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be less effective than using it in liquid form.

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For this reason, appreciating the potential nutritional value of cistus extract in bread

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production, it was decided to study the possibility of using this extract for enrichment of bread

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products. The aim of the study was to analyze and compare selected physicochemical,

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antioxidant, textural and microbiological properties, as well as the technological and

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organoleptic quality of bread in which water was replaced with 2.5, 5 and 7.5% cistus extract

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on the baking day and up to 5 days.

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2. MATERIALS AND METHODS

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2.1. Materials

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The study material consisted of wheat bread (WS) obtained from wheat flour type 550 (PZZ

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Krakow, Poland), the same as used to in previous research (Mikulec et al., 2019), and wheat

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bread in which water prescribed by the recipe was replaced with cistus extract in the

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concentrations 2.5, 5 and 7.5 % w/v (Bellis Pharma sp. z o.o., Jaroslaw, Poland). The dough

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used for baking of bread consisted of 7.5 kg of wheat flour, 4.60 dm³ of cistus extract, 0.23 kg

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of yeast (Lesaffre, S.A., Wolczyn, Poland) and 0.15 kg of salt (Solino, Inowroclaw, Poland).

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The baking was performed twice, each time obtaining 30 pieces of bread.

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2.1.1. Bread preparation

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The dough was prepared using a single-phase method in a fast rotating spiral mixer (Ibis

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MS 130 Poland). After initial fermentation (60 min, 21 ºC, 55% relative humidity (RH)), the

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dough was divided into 405 ± 5 g, pieces, formed and placed in steel molds. After the

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fermentation (in a fermentation cabinet by MIWE GVA (Germany)) (35 min, 32 ºC, 90%

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RH), the bread was baked in an MIWE IDEAL (Germany) batch oven at 230 °C for 32

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minutes. After removal from molds, bread was cooled down for two hours at 19 °C and used

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for further analyses.

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2.2. Methods

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2.2.1. Analysis of basic quality features

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Bread volume was measured by the AACC-approved method 10-05.01 (AACC,

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2000), total baking loss was calculated as the difference between the mass of the raw roll and

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the mass of the roll one hour after baking (Majzoobi, Farahnaky, & Agah, 2011), and crumb

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moisture was estimated using the gravimetric method (AOAC 925.10).

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Analysis of crumb color according to the CIELab system was performed by the

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reflectance method using a Konica Minolta CM-3500d spectrophotometer (Konica Minolta

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Sensing, Osaka, Japan; illuminant D65, observer 10°). The total color difference was

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calculated according to Fernandez-Artigas, Guerra-Hernandez, & Garcia-Villanova (1999)

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using the formula (Eq. 1):

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∆ = √∆

+∆

+∆

(Eq. 1)

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where:

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∆E = the total color difference,

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∆L = brightness difference,

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∆a = redness difference,

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∆b = yellowness difference.

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Color measurements were performed in twelve replicates per loaf. On the basis of L*a*b*

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parameters, the browning index (BI) was estimated (Buera, Retriella, & Lozano, 1985) as

108

follows (Eq. 2):

109

=

[

.

]

(Eq. 2)

.

110

where:

111

=

.

∗

.

∗

∗

∗

.

∗

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L = brightness,

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a = redness,

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b = yellowness.

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2.2.2. Microbiological analysis

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Microbiological analyses of the bread were performed during the 1st and the 5th day of

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storage. Samples were obtained from a different part of the loaf (including the crust and

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crumb). To determine the number of aerobic amylolytic bacteria 1 cm3 of each decimal

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dilution was transferred to three parallel Petri dishes and poured with Waksman medium

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(Biocorp). The plates were incubated at 37 °C for 48 h. The reading of the results consisted in

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filling the plate with Lugol's liquid and counting the colonies around which the yellow, clear

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zone was formed. To determine the number of yeast and mold, from two successive decimal

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dilutions, 1 cm3 was transferred into three parallel Petri dishes and poured with Sabouraud

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agar with chloramphenicol (Biocorp). The plates were incubated at 25 °C for 3 to 5 days. The

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obtained results were counted as cfu/g bread.

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The determination of the microbiological stability of the bread consisted of thermostating the

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product sample at 30 ºC and observing it every 24 hours to determine possible organoleptic

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changes caused by molds or at 37 ºC to determine changes caused by aerobic amylolytic

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bacteria. Time of occurrence of the first organoleptic changes (mold, malleability,

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deformability or crumb viscosity) determined the shelf life of the product. Measurements

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were done in two replicates.

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2.2.3. Texture analysis

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Selected mechanical features of the breadcrumb, such as hardness, springiness, resilience,

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chewiness and gumminess (Szcześniak, 1963), was performed using a single-arm

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TA.XT2.Plus texture analyzer (Stable Micro System Ltd, Godalming, Surrey, United

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Kingdom). Breadcrumb samples were sliced mechanically and the slices for analysis were cut

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from the middle part of the loaf. The tests were done on cylindrical samples (r=30 mm, h=35

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mm). A P/36R aluminum probe with a diameter of 36 mm was used, with the compression

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rate 2 mm·s-1 to reach 50% deformation in two cycles with 5 s waiting time between the

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cycles (Mikulec et al., 2019). Bread for examination of the crumb texture changes during

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storage were packed in polyethylene film pouches (HDPE) and stored at ambient temperature

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(19 ± 1 °C, 60% RH). The analysis was done at 1st and the 5th day of storage. Measurements

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were done in ten repetitions.

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To assess the changes in texture caused by storage, the percentage changes of hardness,

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chewiness, gumminess, springiness and resilience were calculated according to Różyło (2014)

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with modification (Eq. 3): !"# !%#

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=

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Where:

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x 5d = textural property marked after 5 days of storage,

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x 1d = textural property marked after 1 day of storage.

!%#

∗ 100

(Eq. 3)

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2.2.4. Sensory analysis

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Consumer acceptability tests were performed by a panel consisting of 60 untrained consumers

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(20–51 years old, 43 females and 17 males) who were recruited from the Institute of

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Technology (State Higher Vocational School in Nowy Sacz) (staff and students) and who

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were habitual consumers of bread. Assessors were asked demographic questions about age

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and gender and a question about bread consumption. Two hours after baking bread samples

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were sliced mechanically into 20 mm slices and were cooled until bread reached 19 °C. Then

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slices were placed on disposable paper trays and coded with two digits random numbers.

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Samples were presented to the assessors simultaneously. The bread was evaluated only on the

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day of baking using a 9-point hedonic scale (1 = dislike extremely; 2 = dislike very much; 3 =

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dislike moderately; 4 = dislike slightly; 5 = neither like nor dislike; 6 = like slightly; 7 = like

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moderately; 8 = like very much; 9 = like extremely), as described by Meilgaard, Civille, &

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Carr (2007). During the assessment the assessors neutralized the taste using pure water at

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temperature 19 °C. The results were calculated by Microsoft Excel 10.0 software. The

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assessors followed the ethical requirements of the sensory laboratory approved by the State

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Higher Vocational School in Nowy Sacz and an informed consent form was signed by the

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panelists.

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2.2.5. Total phenolic content

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Total phenolic content was estimated using Folin-Ciocalteu reagent (Meda, Lamien, Romito,

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Millogo, & Nacoulma, 2005). Samples were prepared at 0.05 g/mL concentration using water

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solution as described by Mikulec et al. (2019). Results were expressed as mg of gallic acid

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equivalent (GAE) per 100 mg of product. Measurements were done in two replicates.

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2.2.6. Chromatographic analysis of polyphenol profile

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Separation and identification of polyphenols were carried out using high-performance liquid

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chromatography (HPLC) according to the method described by Klimczak, Małecka, Szlachta,

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& Gliszczyńska-Świgło (2007) with modification as described by Mikulec et al. (2019).

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Briefly, Dionex Ultimate 3000 HPLC set equipped with DAD detector (Thermo Scientific,

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Germering, Germany), fitted with Cosmosil 5C18 – MS - II 250 x 4.6 mm ID, 5 µm particle

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size (Nacalai Tesque, INC. Kyoto, Japan) column was used. Gradient elution was used

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(mobile phase: A - 2% aqueous solution of acetic acid, and B - 100% methanol); flow rate

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was 1 mL/min. using the following gradient: Eluent A -0 min 95%, 10 min. 70%; 25 min.

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50%; 35 min. 30%; 40 min. 95%; to the end of analysis. Measurements were done in two

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replicates.

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2.2.7. Statistical analysis

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Statistical analysis was carried out using Statistica 13.0 (StatSoft, Poland). The significance of

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differences was verified with the Duncan test at p<0.05. The results were presented as

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averages ± standard deviation.

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3. RESULTS AND DISCUSSION

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3.1. Analysis of basic quality features

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No influence of cistus extract on baking loss or volume of bread was observed, which ranged

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from 11.13% and 845 cm3 for bread with 7.5% cistus extract to 11.46% and 865 cm3 for

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wheat bread respectively. The moisture content of the crumb on the day of baking did not

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differ significantly among all breads and ranged from 46.34 to 46.96% (Table 1). Similar

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results was observed by Pasrija, Ezhilarasi, Indrani, & Anandharamakrishnan (2015), who

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added a green tea extract and encapsulates to bread and did not observe any change in bread

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volume. Other results were obtained by Cacak-Pietrzak et al. (2019), who observed a

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significant increase in moisture of bread (which increased with cistus content), a baking loss

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from 3 to 5% concentrations of cistus leaves in bread and a decrease in bread volume from

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2% addition of this herb. A similar trend, to that reported by Cacak-Pietrzak et al. (2019) was

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observed in another study by Ning, Hou, Sun, Wan, & Dubat (2017) where specific volume

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decreased with higher concentrations of green tea powder.

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Breads with cistus extract were characterized by significantly lower lightness (brightness) of

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the crumb, compared to wheat bread (Table 1). Bread with cistus extract differed significantly

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in terms of the red component (redness) content (a) in the crumb compared to wheat bread.

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The lowest level was recorded for wheat bread (1.00), and bread with cistus extract ranged

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from 4.25 to 4.29. In the case of the yellowness component (b), wheat bread showed the

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lowest value (20.03), and this value significantly increased with the increase of cistus extract

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content to 27.45 in WCE7.5 (Table 1). The total color difference (△E) increased significantly

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with the increase of cistus extract (Table 1). According to total color difference values, the

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color difference between control and cistus extract bread was perceptible with close

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observation since ∆E values were lower than 3 (Hernández-Carrión et al., 2015). All breads

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differed significantly in terms of the browning index (BI) value. The lowest value was found

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for standard bread (30.92), and the highest was found for WCE7.5 (66.47) (Table 1). Cacak-

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Pietrzak et al. (2019) also observed a significant difference in the color of bread with cistus

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leaves from the control bread. The differences in color parameters of breads were caused by

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the pigments present in Cistus incanus.

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3.2. Microbiological analysis

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The cistus extract contributed to an improvement of the microbiological quality of the bread.

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On the baking day, breads with a cistus extract were characterized by a lower content of

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microorganisms, compared to wheat bread (Table 1). In all breads in which the water was

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replaced by the cistus extract there was observed a decrease in the total number of bacteria

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and the total number of spores of amylolytic bacteria and a reduction of total number of

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aerobic amylolytic bacteria on the fifth day of storage. Inhibition of microbiological changes

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in bread with 7.5% cistus extract was observed, compared to wheat bread (Table 1).

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The time of occurrence of the first organoleptic changes and the positive thermostat test result

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determined the shelf life of the product. When analyzing thermostatic stability, there were

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observed in wheat bread crumb, from the 3rd day of storage, both visible mold (Aspergillus

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niger) and changes in the crumb indicating the development of Bacillus bacteria (soft, sticky

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and viscous breadcrumb). In the WCE2.5 and WCE5 bread, no mold-like changes were

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observed until the 5th day, but from the 3rd day changes in the crumb indicating the

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development of Bacillus bacteria were visible. In WCE7.5 bread, no mold-like changes were

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observed and the bacterial-like changes were characterized by slight variation. Based on these

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results it can be concluded that the addition of cistus extract contributed to improvement of

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the microbiological quality of the tested bread.

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The obtained effect may result from the antibacterial properties of the cistus extract observed

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by Barrajón-Catalán et al. (2010) in their studies. They observed antibacterial properties of

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extracts from Cistus ladanifer, which inhibits growth of the Gram-positive bacterium

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Staphylococcus aureus, and extract from Cistus populifolius reveals high growth inhibitory

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activity against the Gram-negative bacterium Escherichia coli. Tomás-Menor et al. (2013)

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posited that the cause of the inhibitory activity against bacteria may be related to the presence

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of galloylated flavanols and specific flavonols and polar compounds and to other flavonols.

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3.3. Texture analysis

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The stalling process leads to changes in the texture and reduction of fresh bread

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characteristics, which results in a short shelf life and best before date (Gray & Bemiller, 2003;

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Ribotta & Le Bail, 2007). During storage (up to 5 days) an increase in breadcrumb hardness

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was observed for all breads. The largest increase was characterized by standard wheat bread,

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as much as 72.89%, compared to the first day of storage, and the smallest for WCE5 bread

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(29.03%). There was a reduction in the springiness and resilience of all loaves at a similar

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level. The largest increase in gumminess and chewiness was observed in wheat bread,

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whereas in bread with cistus extract a reduction of chewiness was observed. The greatest

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variability of texture parameters was identified for breadcrumb of standard wheat bread

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(Table 1) and the smallest for bread with cistus extract, which can be considered as an

253

inhibitor of staling of the breadcrumb. Others authors have observed different dynamics of

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changes in the texture features of bread, both increases and decreases of such parameters as

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hardness, springiness, cohesiveness, and chewiness depending on the form of the additive.

256

The changes of bread crumb texture are probably a result of change in the nature of starch,

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dilution of gluten and enrichment of fibre. It can be seen that the addition of herbal extracts

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had a rather positive effect on the textural properties of the bread (Cacak-Pietrzak et al., 2019;

259

Ning et al., 2017; Pasrija et al., 2015).

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3.4. Sensory analysis

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In the organoleptic evaluation, wheat bread and bread with a 2.5% cistus extract did not differ

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statistically significantly and obtained the highest average marks for specific characteristics,

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which ranged from 8.8 to 8.9 and 8.7 to 8.8 respectively (Figure 1). Bread with 5% and 7.5%

264

of cistus extract differed significantly in the results of the sensory evaluation compared to WS

265

and WCE2.5. Breads with 5 and 7.5% cistus extract did not differ significantly for taste and

266

smell or crumb porosity. The scores for other features were statistically different. WCE5 and

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WCE7.5 received the lowest marks for taste and smell (7.5 and 7.3 respectively) (Figure 1).

268

Bread with a 5% cistus extract received the highest marks for appearance and crumb porosity

269

(8.6 and 8.5 respectively) and bread with a 7.5% cistus extract for crumb porosity (8.3) and

270

appearance and crust thickness (8.1.) (Figure 1). Cacak-Pietrzyk et al. (2019) observed

271

deterioration in the organoleptic characteristics of taste, aroma and overall acceptability with

272

a 4% addition of the cistus leaves. Deterioration of the organoleptic properties of bread which

273

were observed in our research can also be seen in bread enriched with herbs such as basil,

274

oregano, and thyme, which can be explained by the content of essential oils that cause its

275

specific taste and smell (Adams, Kruma, Verhé, De Kimpe, & Kreicbergs, 2011).

276

3.5. Total polyphenol content and chromatographic analysis of polyphenol profile

277

The addition of the cistus extract clearly contributed to increasing the antioxidative potential

278

of the obtained bread products (Table 2). Breads with the addition of cistus extract were

279

characterized by a higher total polyphenol content, from 62.81 to 105.81 mg GAE per 100 g

280

of product, compared to the standard (41.23 mg GAE per 100 g). Along with the addition of a

281

more concentrated cistus extract, an increase in the sum of polyphenols determined

282

chromatographically in breads was observed from 34.68 (WCE2.5) to 78.71 mg/100 g

283

(WCE7.5). Cacak-Pietrzak et al. (2019) and Lisiecka et al. (2019), who enriched pasta and

284

bread with dried cistus leaves, observed significantly higher TPC and much higher

285

antioxidant activity of breads and pasta compared to the control sample. The bread enriched

286

with Cistus incanus was characterized by significantly higher TPC already at 1% of the

287

amount of this additive (Caca-Pietrzak et al., 2019). Breads enriched with herbs are

288

characterized by beneficial features in many aspects such as high antioxidant content (Ibrahim

289

et al., 2015). Cistus herb exhibited the highest content of polyphenols (2635.16 mg/100 g),

290

and the dominant polyphenols were (+) catechin (726.65) and ellagic acid (637.18 mg/100 g)

291

(Table 2). Wheat flour and wheat bread were characterized by the lowest polyphenol content

292

(8.50 and 8.88 mg/100 g respectively). No rutin, ellagic acid, 3-hydroxybenzoic acid, (+)

293

catechin, protic acid or t-cinnamic acid was found in the wheat flour or wheat bread in the

294

polyphenol profile. Chlorogenic and t-cinnamic acid were not found in bread with cistus

295

extract despite being present in the cistus herb (93.10 and 0.12 mg/100 g respectively). The

296

content of polyphenols in bread obtained with the addition of cistus extract increased as a

297

result of the substitution of water with this extract. Nevertheless, the polyphenol profile

298

showed quantitative, as well as qualitative, changes. Gallic acid appeared in wheat bread

299

(2.14), but was not present in wheat flour, and there was no phloridzin in wheat bread,

300

although it was detected in wheat flour (0.74 mg/100 g). Some fluctuations were also

301

observed in the content of the other polyphenols. In contrast to the other polyphenols

302

measured by chromatography, more ferulic acid and rutin were determined in bread with the

303

cistus extract in comparison to the amount resulting from the calculation (Table 2). These

304

changes are the result of heat treatment (baking process). Riehle, Vollmer, and Rohn (2013)

305

reported that when preparing C. incanus beverages, decreased amounts of phenolic substances

306

and reduced antioxidant activity are observed if an incorrect selection of brewing process

307

parameters (brewing water, temperature, and duration) is made. Spontaneous changes in

308

polyphenols can occur at elevated temperatures. Such relationships were also observed in the

309

case of grape pomace heating (Chamorro, Goni, & Viveros, 2012). A significant increase in

310

the total polyphenol content was also observed, along with an increase in the cistus extract

311

content in bread (Table 2).

312

4. CONCLUSION

313

Cistus extract has a high nutritional and pro-health value, so it could be used as a valuable

314

component of bread. To date there are no studies concerning utilization of cistus extract in

315

bread formulations, so the research was

316

microbiological, and organoleptic characteristics, polyphenol profile and the total polyphenol

317

content as nutrients in bread. Cistus extract influenced the color of the crumb by increasing its

318

browning index in comparison to wheat bread. The total color difference (△E) increased

319

significantly with the increase of cistus extract and the total color difference between control

320

and cistus extract breads was perceptible with close observation. The cistus extract positively

321

influenced microbiological properties of bread enhancing its shelf life. Both on the day of

322

baking and after 5 days of storage bread with a cistus extract was characterized by a lower

323

content of microorganisms, compared to wheat bread. During storage (up to 5 days) the

focused on selected physicochemical,

324

greatest variability of texture parameters was identified for wheat breadcrumb and the

325

smallest for bread with cistus extract, which can be considered as an inhibitor of staling of the

326

breadcrumb. The observed effect is advantageous, because crumb hardening is one of the

327

main symptoms of bread staling. The addition of the cistus extract positively influenced

328

antioxidant properties of bread by increasing the total polyphenol content. The results show

329

that preparations, based on cistus extract, may be valuable components of bread significantly

330

improving its nutritional and pro-health value, with almost unchanged sensory attributes and

331

limiting the aging of the bread.

332 333

ACKNOWLEDGEMENTS

334

This Research was finance by the Ministry of Science and Higher Education of the Republic

335

of Poland.

336

Statistical analysis was performed using the skills acquired during the training entitled

337

"Application of statistics and Statistica in planning empirical research and developing its

338

results in natural sciences - basic methods" implemented as part of the project: "Integrated

339

Program of the Agricultural University H. Kołłątaja w Krakowie ”, co-financed from

340

European Union funds.

341

Declarations of interest: none.

342 343

REFERENCES

344 345

1. Adams, A., Kruma, Z., Verhé, R., De Kimpe, N., & Kreicbergs, V. (2011). Volatile

346

profiles of rapeseed oil flavored with basil, oregano, and thyme as a function of

347

flavoring conditions. Journal of the American Oil Chemists' Society, 88(2), 201–212.

348

https://doi.org/10.1007/s11746-010-1661-3.

349 350 351 352

2. AACC. (2000). Approved Methods of the AACC (10th ed.). St Paul, MN, USA: American Association of Cereal Chemists. 3. AOAC. (2006). Official Methods of Analysis (18th ed.). Gainthersburg, MD: AOAC Association of Analytical Chemists International.

353

4. Barrajón-Catalán, E., Fernández-Arroyo, S., Saura, D., Guillén, E., Fernández-

354

Gutiérrez, A., Segura-Carretero, A., & Micol, V. (2010). Cistaceae aqueous extracts

355

containing ellagitannins show antioxidant and antimicrobial capacity, and cytotoxic

356

activity against human cancer cells. Food and Chemical Toxicology, 48(8-9), 2273-

357

2282. https://doi.org/10.1016/j.fct.2010.05.060.

358

5. Benkhnigue, O., Hachi, M., Fadli, M., Douira, A., & Zidane, L. (2016). Catalogue of

359

the medicinal plants used in the treatment of urinary infections in the area of al-haouz

360

rhamna (central morocco). European Journal of Botany, Plant Sciences and

361

Phytology, 3 (1), 1-49.

362 363

6. Buera, M. P., Retriella, C., & Lozano, R. D. (1985). Definition of colour in the nonenzymatic browning. Die Farbe, 33, 316–326.

364

7. Cacak-Pietrzak, G., Różyło, R., Dziki, D., Gawlik-Dziki, U., Sułek, A., & Biernacka,

365

B. (2019). Cistus incanus L. as an innovative functional additive to wheat bread.

366

Foods, 8, 349. https://doi.org/10.3390/foods8080349.

367

8. Chamorro, S., Goni, I., & Viveros, A. (2012). Changes in polyphenolic content and

368

antioxidant activity after thermal treatments of grape seed extract and grape pomace.

369

European Food Research and Technology, 234, 147–155.

370 371

9. Duke, J., Duke, P. A. K., & duCellier, J. (2008). Duke’s handbook of medicinal plants of the Bible (1th ed.). Boca Raton: CRC Press, 113-115.

372

10. Fernandez-Artigas, P., Guerra-Hernandez, E., & Garcia-Villanova, B. (1999).

373

Browning indicators in model systems and baby cereals. Journal of Agricultural and

374

Food Chemistry, 47, 2872–2878.

375 376

11. Gray, J. A., & Bemiller, J. N. (2003). Bread staling: molecular basis and control. Comprehensive Reviews in Food Science and Food Safety, 2(1),1–21.

377

12. Hernández-Carrión, M., Sanz, T., Hernando, I., Llorca, E., Fiszman, S. M., & Guiles,

378

A. (2015). New formulations of functional white sauces enriched with red sweet

379

pepper. A rheological, microstructural and sensory study. European Food Research

380

and Technology, 240, 1187–1202.

381

13. Hutschenreuther, A., Birkemeyer, C., Grötzinger, K., Straubinger, R. K., Rauwald, H.

382

W. (2010). Growth inhibiting activity of volatile oil from Cistus creticus L. against

383

Borrelia

384

https://doi.org/10.1691/ph.2010.9762.

burgdorferi

s.s.

in

vitro.

Die

Pharmazie,

65

(4),

290-295.

385

14. Ibrahim, U. K., Salleh, R. M., & Maqsood-ul-Haque, S. N. S. (2015). Bread towards

386

functional food: An overview. International Journal of Food Engineering, 1 (1), 39-

387

43.

388

15. Klimczak, I., Małecka, M., Szlachta, M., & Gliszczyńska-Świgło, A. (2007). Effect of

389

storage on the content of polyphenols, vitamin C and the antioxidant activity of orange

390

juices. Journal of Food Composition and Analysis, 20, 313-322.

391

16. Kuchta, A., Konopacka, A., Waleron, K., Viapiana, A., Wesołowski, M., Dąbkowski,

392

K., Ćwiklińska, A., Mickiewicz, A., Śledzińska, A., Wieczorek, E., Gliwińska, A.,

393

Kortas-Stempak, B., & Jankowski, M. (2019). The effect of Cistus incanus herbal tea

394

supplementation on oxidative stress markers and lipid profile in healthy adults.

395

Cardiology Journal. https://doi.org/10.5603/CJ.a2019.0028.

396

17. Küpeli, E., & Yesilada, E. (2007). Flavonoids with anti-inflammatory and

397

antinociceptive activity from Cistus laurifolius L. leaves through bioassay-guided

398

procedures. Journal of Ethnopharmacology, (112), 524-530.

399

18. Lisiecka, K., Wójtowicz, A., Dziki, D., & Gawlik-Dziki, U. (2019). The influence of

400

Cistus incanus L. leaves on wheat pasta quality. Journal of Food Science and

401

Technology. https://doi.org/10.1007/s13197-019-03900-9.

402

19. Majzoobi, M., Farahnaky, A., & Agah, Sh. (2011). Properties and shelf-life of part-

403

and full-baked flat bread (Barbari) at ambient and frozen storage. Journal of

404

Agricultural Science, 13, 1077-1090.

405

20. Meda, A., Lamien, C. E., Romito, M., Millogo, J., & Nacoulma, O. G. (2005).

406

Determination of the total phenolic, flavonoid and proline contents in Burkina Fasan

407

honey, as well as their radical scavenging activity. Food Chemistry, 91, 571–577.

408 409

21. Meilgaard, M. C., Civille, G. V., & Carr, B. T. (2007). Sensory Evaluation Techniques (4th Ed.). New York: CRC Press, (Chapters 10 &12).

410

22. Mikulec, A., Kowalski, S., Sabat, R., Skoczylas, Ł., Tabaszewska, M., & Wywrocka-

411

Gurgul, A. (2019). Hemp flour as a valuable component for enriching

412

physicochemical and antioxidant properties of wheat bread. LWT – Food science and

413

Technology, 102, 164-172. https://doi.org/10.1016/j.lwt.2018.12.028.

414

23. Ning, J., Hou, G.G., Sun, J., Wan, X., & Dubat, A. (2017). Effect of green tea powder

415

on the quality attributes and antioxidant activity of whole-wheat flour pan bread. LWT

416

-

417

https://doi.org/10.1016/j.lwt.2017.01.052.

Food

Science

and

Technology,

79,

342–348.

418

24. Pasrija, D., Ezhilarasi, P.N., Indrani, D., & Anandharamakrishnan, C. (2015).

419

Microencapsulation of green tea polyphenols and its effect on incorporated bread

420

quality.

LWT

-

Food

Science

421

https://doi.org/10.1016/j.lwt.2015.05.054.

and

Technology,

64,

289–296.

422

25. Rebensburg, S., Helfer, M., Schneider, M., Koppensteiner, H., Eberle, J., Schindler,

423

M., Gürtler, L., & Brack-Werner, R. (2016). Potent in vitro antiviral activity of Cistus

424

incanus extract against HIV and Filoviruses targets viral envelope proteins. Scientific

425

Reports, 6. https://doi.org/10.1038/srep20394.

426

26. Ribotta, P. D., & Le Bail, A. (2007). Thermo-physical assessment of bread during

427

staling.

LWT

–

Food

Science

428

https://doi.org/10.1016/j.lwt.2006.03.023.

and

Technology,

40

(5),

879-884.

429

27. Riehle, P., Vollmer, M., & Rohn, S. (2013). Phenolic compounds in Cistus incanus

430

herbal infusions—antioxidant capacity and thermalstability during hebrewing process.

431

Food

432

https://doi.org/10.1016/j.foodres.2012.09.020.

Research

International,

53

(2),

891–899.

433

28. Różyło, R. (2014). New potential of using millet-based yeast-fermented leaven for

434

composite wheat bread preparation. Journal of Food and Nutrition Research, 53, 240-

435

250.

436

29. Sayah, K., Chemlal, L., Marmouzi, I., El Jemli, M., Cherrah, Y., & My El Abbes, F.

437

(2017). In vivo anti-inflammatory and analgesic activities of Cistus salviifolius (L.)

438

and Cistus monspeliensis (L.) aqueous extracts. South African Journal of Botany, 113,

439

160-163. https://doi.org/10.1016/j.sajb.2017.08.015.

440 441

30. Szcześniak, A. S. (1963). Classification of textural characteristics. Journal of Food science, 28, 385-389.

442

31. Tomás-Menor, L., Morales-Soto, A., Barrajón-Catalán, E., Roldán-Segura, C., Segura-

443

Carretero, A., & Micol, V. (2013) Correlation between the antibacterial activity and

444

the composition of extracts derived from various Spanish Cistus species. Food and

445

Chemical Toxicology, 55, 312-322. https://doi.org/10.1016/j.fct.2013.01.006.

446

32. Viapiana, A., Konopacka, A., Waleron, K., & Wesołowski, M. (2017). Cistus incanus

447

L. commercial products as a good source of polyphenols in human diet. Industrial

448

Crops and Products, 107, 297-304. https://doi.org/10.1016/j.indcrop.2017.05.066.

449

33. Vitali, F., Pennisi, G., Attaguile, G., Savoca, F., & Tita, B. (2011). Antiproliferative

450

and cytotoxic activity of extracts from Cistus incanus L. and Cistus monspeliensis L.

451

on

452

https://doi.org/10.1080/14786410802583148.

human

prostate

cell

lines.

Natural

Product

Research,

25,

188-202.

453 454

Figure captions

455

Figure 1. Results of organoleptic analysis of tested breads

456

Explanatory notes:

457

…….

458

with 5 % cistus extract, ⸺ WCE7.5 – bread with 7.5 % cistus extract

WS – wheat bread, - - - WCE2.5 – bread with 2.5 % cistus extract, ⸺⸺ WCE5 – bread

Table 1. Evaluation of selected quality parameters of studied breads Bread type

WS*

WCE2.5

WCE5

WCE7.5

Physico-chemical parameters of bread Total baking loss [%]

11.46**a ± 0.42

11.16a ± 0.26

11.33a ± 0.28

11.13a ± 0.34

Volume [cm³]

865.00a ± 17.84

859.67a ± 15.17

856.67a ± 12.89

845.0a ± 16.46

Moisture of bread crumb [%]

46.81a ± 0.08

46.96a ± 0.19

46.34a ± 0.13

46.48a ± 0.96

Color parameters of bread crumb c

L*** [-]

75.17** ± 0.87

60.86b ± 0.77

58.94a ± 0.78

58.18a ±0.78

a [-]

1.00a ± 0.08

4.29b ± 0.16

4.25b ± 0.22

4.26b ± 0.22

b [-]

20.03a ± 0.74

22.53b ± 0.46

25.41c ± 0.54

27.45d ± 0.40

a

b

∆E [-]

-

14.90 ± 0.73

17.41 ± 0.48

18.83c ± 0.75

BI [-]

30.92a ± 1.68

49.85b ± 1.28

59.53c ± 1.91

66.47d ± 1.94

Microbiological characteristic of bread (cfu / g) I day TNB****

1.9 x 103

3.3 x 101

4.7 x 101

3.0 x 101

NAAB

1.1 x 103

3.0 x 101

2.7 x 101

2.3 x 101

NSAB

6.7 x 102

2.0 x 101

6.8 x 101

0.5 x 100

Microbiological characteristic of bread (cfu / g) V day TNB

8.3 x 105

4.2 x 105

2.2 x 105

1.6 x 104

NAAB

8.1 x 105

0.0

6.0 x 104

0.0

NSAB

4.2 x 105

1.8 x 104

1.5 x 101

4.0 x 103

Changes in texture after five day storage [%] Hardness [N]

72.89c ± 2.31

36.73b ± 0.51

29.03a ± 0.47

29.27a ± 0.33

Springiness [-]

-7.61b ± 0.57

-8.78ab ± 0.66

-8.49ab ± 0.33

-9.09a ± 0.59

Gumminess [N]

19.59d ± 1.01

2.25a ± 0.11

3.04b ± 0.09

5.14c ± 0.25

Chewiness [N x mm]

8.44d ± 0.44

-2.62c ± 0.09

-9.77a ± 0.37

-6.62b ± 0.12

Resilience [-]

-33.33a ± 1.01

-40.00b ± 0.91

-40.00b ±1.11

-40.63b ± 1.29

Explanatory notes: * WS – wheat bread. WCE2.5 – bread with 2.5 % cistus tea. WCE5 - bread with 2.5 % cistus tea. WCE7.5 - bread with 7.5 % cistus tea **values in the same row marked with different letters are statistically significantly different at p≤ 0.05 ± SEM *** L – lightness. a – redness. b – yellowness. △E- total color difference. BI - browning index ****TNB - total number of bacteria. NAAB - total number of aerobic amylolytic bacteria. NSAB- total number of spores amylolytic bacteria

Table 2. Polyphenol profile and the total polyphenol content of bread Sample

chlorogenic acid

p-coumaric acid

ferulic acid

rutin

ellagic acid

phloridzin

3hydroxybenzo ic acid

(+) catechin

protic acid

gallic acid

t-cinnamic acid

total

TPC***

mg GAE* 100g-1

[mg*100g-1] Wheat flour WF550*

0.00**±0.00

0.30±0.02

7.46±0.20

0.00±0.00

0.00±0.00

0.74±0.08

0.00±0.00

0.00±0.00

0.00±0.00

0.00±0.00

0.00±0.00

8.50±0.23

0.00±0.00

8.88c±0.15

48.12±0.77

Bread d

c

WS

0.00±0.00

0.30 ±0.01

6.43 ±0.13

0.00±0.00

0.00±0.00

0.00±0.00

0.00±0.00

0.00±0.00

0.00±0.00

2.14c±0.06

WCE2.5

0.00±0.00

1.07c±0.01

7.34a±0.25

2.85b±0.12

9.10c±0.41

1.17c±0.08

1.78b±0.41

6.94c±0.91

2.50c±0.49

1.93c±0.06

0.00±0.00

34.68b±1.58

WCE5

0.00±0.00

1.81a±0.02

7.01b±0.16

7.36a±0.49

23.40b±2.39

1.56b±0.08

4.11a±0.66

16.40b±1.44

5.93b±0.47

4.80b±0.36

0.00±0.00

72.38a±5.71

WCE7.5

0.00±0.00

2.26a±0.03

6.51c±0.18

7.72a±0.14

26.57a±0.34

1.83a±0.03

3.87a±0.55

18.20a±0.72

6.56a±0.19

5.19a±0.10

0.00±0.00

78.71a±0.89

cistus 93.10±1.77 73.95±10.27 35.48±4.17 231.55±8.44 637.18±53.00 37.59±0.51 192.90±4.74 726.65±118.9 313.69±68.75 herb 4 cistus extract 2.33 1.85 0.89 5.79 15.93 0.94 4.82 18.17 7.84 ****2.5% cistus extract 4.66 3.69 1.77 11.58 31.86 1.88 9.65 36.33 15.68 ****5.0% cistus extract 6.98 5.55 2.66 17.37 47.79 2.82 14.47 54.49 23.53 ****7.5% Explanatory notes: * WF- wheat flour, WS – wheat bread, WCE2.5 – bread with 2.5 % cistus tea, WCE5 - bread with 2.5 % cistus tea, WCE7.5 - bread with 7.5 % cistus tea **values in the same column marked with different letters are statistically significantly different at p≤ 0.05 ± SEM *** TPC –the total phenolic content **** values calculated on the basis of individual compound concentration in cistus herb

292.94±11.07

0.12±0.02

2635.16±243.37

7.32

0.00

65.88

14.65

0.01

131.76

21.97

0.01

197.64

41.23d±0.7 3 62.81c±0.70 82.73b±0.5 1 105.81a±2.1 5

Cistus 930.76 ±9.72 23.27 36.55 69.81

1. Cistus extract enhanced antioxidant properties of bread 2. Cistus extract had a positive effect on textural features of the bread 3. Cistus extract inhibited the growth of microflora improving shelf life of bread 4. Cistus extract influenced the color of the crumb by increasing its browning index

Declaration of interests ☒ The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper. ☐The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: