EVALUATION OF RHEOLOGICAL PARAMETERS OF DOUGH WITH FERROUS LACTATE AND FERROUS GLUCONATE
Рубрики: RESEARCH ARTICLE
Аннотация и ключевые слова
Аннотация (русский):
The aim of this study was to analyse the effect ferrous gluconate and ferrous lactate on the rheological be- haviour of dough from a high extraction rate. For fortification of wheat flour, we used iron ions in a divalent form in amounts of 3, 4, and 5 mg/100 g. To record the rheological characteriscics of the fortified wheat flour dough, Farino- graph, Amilograph, Falling Number, Rheofermentometer, and Thermo Haake Mars dynamic rheometer were applied. The Farinograph did not show significant changes in the water absortion values in the samples with ferrous salts. As for dough development time and dough stability, small amounts of ferrous additives increased and large amounts de- creased those parameters. The effect was more significant in the samples with ions from gluconate form than from lactate salt. The Amylograph recorded an increased peak viscosity with an increasing ferrous salt quantity. That was the case for both ferrous salt forms. The increased was in a similar way for both types of ferrous salt forms used. The total CO volume production and the retention coefficient obtained with the help of the Rheofermentometer device increased in the dough samples with 3 and 4 mg of iron/100 g. However, the addition of 5 mg of iron decreased those indicarors. The decrease was more significant for iron ions from ferrous ferrous gluconate than from ferrous lactate. The fundamental rheological properties of the dough were analysed by using a frequency sweep and oscillatory tem- perature sweep test. Ferrous lactate and ferrous gluconate influenced both the fundamental and empirical rheological properrties og the dough in similar way.

Ключевые слова:
Wheat flour, ferrous lactate, ferrous gluconate, rheological properties
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Iron is a vital element for the humans, hence iron deficiency can seriously affect human’s health [1, 2]. 60% of the world’s population was estimated to be defi- cient in iron, while 33%, 30% and 15% are deficient in zinc, iodine, and selenium, respectively. Such a status is known as ‘hidden hunger’, due to diet that is poor in es- sential micronutrients [3, 4]. Iron deficiency has reached epidemic levels in numerous developing countries and affects people of all ages worldwide [5, 6]. The func- tional iron pool consists of such structural components in heme proteins as hemoglobin, myoglobin, and cyto- chromes [6, 7]. In addition, iron plays a part in nearly all redox reactions, and it is a vital component in several en- zymes [3].

Iron aids the distribution of oxygen to the body, keeps the immune system strong, and helps the body to produce energy. Iron deficiency is caused by an insufficient iron

 

intake, a poor absorption of iron or both. Iron deficien- cy exerts an adverse effect on mental and motor function, work productivity, immunity, cognitive development, and the quality of life in general [3, 5, 8, 9].

In 2012 WHO (World Health Organization) imple- mented a plan on maternal, infant, and young child nutri- tion to achieve a 50% reduction of anaemia by 2025 [10]. The food industry has initiated the use of iron into con- sumer products such as bread, breakfast cereals, biscuits, and energy bars. The food vehicles recommended to be fortified with iron, apart from staple foods, seasonings (i.e. table salt, soy sauce, fish sauce, broth, and curry powder) have been assayed owing to their extensive use in the various target populations [10]. The fortifying in- gredients should however be used in the recommended amounts to prevent the risk of excessive consumption. Blanco-Rojo, Vaquero, and Hurrell [10, 11] reported that iron was the most difficult micronutrient to produce for- tified foods. Many of the compounds used as iron forti-

 

 

Copyright © 2019, Codină et al. This is an open access article distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material for any purpose, even commercially, provided the original work is properly cited and states its license.

 

 

 

ficants caused unacceptable colour and flavour changes

in foods.

Cereal is the main source of food for humans, espe- cially in developing countries where it takes half of the calorie intake. The most appropriate iron compounds recommended by the WHO to fortify cereals are fer- rous sulfate, ferrous fumarate, ferric pyrophosphate, and electrolytic iron [10, 12]. Most nutrients are present in the outer layers of wheat and are lost during the milling process. Wheat flour is the raw material in the manufac- turing of many foods: bread and bakery products, con-

 

by S.C. Dizing S.R.L. (Brusturi. Neam,  Romania). The following characteristics of wheat flour were ana- lysed according to Romanian or international stan- dard  methods:  moisture  (ICC  110/1)*,  ash   con- tent (ICC 104/1)**, protein content (ICC 105/2)***, gluten deformation index (SR 90:2007), wet gluten (ICC 106/1), and Falling Number (ICC 107/1)****. The an- alytical  characteristics  for   the   wheat   fl   analysed were the following: 1.25 g/100 g for ash content, 12.8% for moisture,  14.3%  for  protein,  35%  for  wet  gluten, 3 mm for gluten deformation index, and 262 s for Falling

 

fectionery products, snacks, and biscuits. In Romania,

 

Number. Ferrous gluconate (Fe(C H

 

O ) ·2H O) and fer-

 

wheat flour has been the only food item widely used for

 

rous lactate (Fe (CH

 

6    11    7  2

 

2

provided

 

CH(OH)COO) ·2H O) were

 

iron fortification at the national level [13]. An alternative

 

3

by Jost Chemical

 

2

The

 

2

salts were ad-

 

(Belgium).

 

ferrous

 

source of this element for the treatment of iron deficiency

can be iron fortified bread [3].

Besides flour, bread and other fortified products also contain a number of various ingredients and food addi- tives. Iron can interact with these, which can cause taste, odour and colour changes, enchance the toxicity of ad- ded food additives, or decrease the vitamin and miner- al content in the products. The rheological properties of fortified dough, among other parameters, change [14, 15] during the technological process.

For successful fortification programme, it is impo- rtant that the combination of the fortificant and the food item to be easily accepted by the comsumer [16, 17]. This requirement includes not only sensory properties of the fortified food but also economic viability and effica- cy (bioavailability) [17, 18]. The interactions between the iron fortificant, the food vehicle and the consumer accep- tance can be the subject of a further investigation and a multidisciplinary approach [10].

Iron in other products of plant origin is non-heme, and its disadvantage is to interact with substances  in foods that inhibit its absorption such as tannins, phytates,

 

ded in suce a way to achieve the iron ion concentration in

wheat fl      of 3 mg/100 g, 4 mg/100 g, and 5 mg/100 g.

The empirical rheological tests during mixing, pa- sting, and fermentation processes of wheat flour dough with and without iron ions addition were carried  out using Farinograph, Amilograph, Falling Number, and Rheofermentometer devices.

Empirical rheological properties of the dough during mixing were evaluated by using a Farinograph device (Brabender,  Duigsburg, Germany, 300  g capa- city) according to ICC method 115/1*****. We ana- lysed  water  absorption  (WA,  %),  dough  stability (ST, min), dough development time (DT, min), and de- gree of softening (DS, min) at 10 min.

max

 
Viscometric rheological properties of the dough were analysed with the help of a Falling Number device (Perten Instruments AB, Sweden) and an Amylograph device (Brabender OGH, Duisburg, Germany). ICC method 107/1 was used to evaluate the α-amylase acti- vity of the wheat flour through the Falling number values (FN, s). Such parameters as gelatinization temperature

 

max

 
and polyphenols. Therefore, iron has a low bioavailabi-

(Tg, °C), peak viscosity (PV

 

, BU), and temperature at

 

lity [19]. The most significant enhancer of iron bioavai-

 

peak viscosity (T

 

, °C) were determined according to

 

lability is ascorbic acid, which both reduces and chelates

iron, rendering it soluble and availability for absorption in the gut [6, 20].

Fortification of wheat flour with iron is technically more difficult than that with other nutrients because iron

 

ICC method 126/1******.

Dough rheological properties during fermentation were measured with a Chopin Rheofermentometer (Cho- pin Rheo, type F3, Villeneuve- La- Garenne Cedex, France). The parameteres were: maximum height of ga-

 

is a pro-oxidant and therefore promotes lipid oxidation.

 

seous production (H’m, mm), total CO

 

volume produc-

 

Hence, the ideal iron compound for fortification of food

 

tion (VT), volume of the gas retained

 

2

in the dough at the

 

should be one that ensures high iron bioavailability and

does not affect the nutritional value or sensory proper- ties of food [21–23]. Therefore, that waa the reason why we chose ferrous lactate and ferrous gluconate as an iron source. Theese froous salts ensure a high bioalvalabilty

 

end of the test (VR), and retention coefficient (CR, %).

Fundamental dough rheological properties were analysed using a HAAKE MARS 40 rheometer. The dough samples had  the  optimum  dough  consisten- cy  according  to  the  water  absortion  values  previosly

 

[24, 25], so they are widely reccommened as iron source                                                                     

 

for food products. In this paper we analysed an effect of fortification of wheat flour from a high extraction rate with iron ions in a divalent form from ferrous lactate and ferrous gluconate in amounts of 3, 4 and 5 mg/100 g on the rheological behaviour of the flour To our knowledge no such complex study on empirical (mixing, pasting, and fermentation) and fundamental rheological behaviour of gough was made using this type of iron ions.

 

STUDY OBJECTS AND METHODS

The  wheat  flour  used  in  this  study  was  provided

 

* Standard Method 110/1. Determination of the Moisture Content of Cereals and Cereal Products (Practical method).

** Standard Method 104/1. Determination of Ash in Cereals and Cereal Products.

*** Standard Method 105/2. Determination of Crude Protein in Cereals and Cereal Products for Food and Feed.

**** Standard Method 107/1. Determination of  the  ‘Falling  Num- ber’ according to HagbergPerten as a Measure of the Degree of Al- pha-Amylase Activity in Grain and Flour.

***** Standard Method 115/1. Method for using the Brabender Fari- nograph.

****** Standard Method 126/1: Method for using the Brabender Amy-

lograph.

 

 

 

established  by  the  Farinograph  device.  Each  sample was placed between the rheometer plates. The excess

 

Table 1. Effects of iron ions from the gluconate and lactate salts on Farinograph rheological properties

 

Iron ions,

mg per 100 g/salt type

WA, %

DT, min

ST, min

DS, BU

0 (control)

65.0 ± 0.02

5.7 ± 0.01

7.3 ± 0.02

31 ± 0.02

3/FG

65.4 ± 0.01

6.2 ± 0.02

8.2 ± 0.02

28 ± 0.01

4/FG

64.9 ± 0.01

2.2 ± 0.02

7.9 ± 0.02

25 ± 0.01

5/FG

64.7 ± 0.02

2.2 ± 0.01

7.7 ± 0.03

24 ± 0.03

3/FL

65.1 ± 0.01

5.2 ± 0.01

7.8 ± 0.03

27 ± 0.02

4/FL

65.0 ± 0.02

2.0 ± 0.02

7.4 ± 0.02

24 ± 0.03

5/FL

64.6 ± 0.03

2.0 ± 0.03

7.0 ± 0.03

22 ± 0.03

 

 
margins of the samples was removed and vaseline oil                                                                                                              was used to prevent drying of the dough samples. The

gap was setted to 2 mm, and a plate system with a di- ameter of 40 mm was used. Before analysis, the dough samples were left between plates for 10 min in order to allow its relaxation and to eliminate the stress rsul- ting from the mixing process. Frequency sweep  tests from 0.00 to 20 Hz  were  performed  at  25°C  for  all the dough samples. For the  temperature  sweep  test, the samples were heated from 20 to 100°C at a hea- ting rate of 4°C per min at a fixed frequency of 1 Hz and a strain of 0.001. During the frequency sweep tests and

 

during heating storage modulus (G’) and loss modulus (G”) were analysed.

Statistical analysis of the triplicate results obtained was done using the XLSTAT statistical package (free trial version 2016, Addinsoft, Inc., Brooklyn, NY, USA), at a significance level of p < 0.05.

 

RESULTS AND DISCUSSION

Table 1 demonstrates the empirical rheological prope- rties of dough samples with or without iron ions during mixing which were analysed by the Farinograph device.

As one can see in Table 1, water absortion values did not signifcantly change in the samples with the iron ions. A slightly decrease of these values were noticed in the samples with large amounts of iron ions. This might be due to the fact that salt ions are able to modify hydrogen and hydrophobic interactions with the wheat flour com- ponents and lead to protein-water interactions instead of protein ones [26].

Increased amounts of iron ions addition decreased the dough development time significantly (p < 0.001) for both types of salts. An explanation of that was probably gluten proteins interactions modified by iron salts. They would possibly present more positive electric charge which might favor a less interaction in a shorter mixing time. Also, dough stability decreased more significqantly at high levels of iron ions addition in the case of gluco-

 

Note: 0 is the sample without iron ions; FG is ferrous gluconate; FL is ferrous lactate; WA is water absorption; DT is dough develop- ment time; ST is stability; DS is degree of softening at 10 min

 

nate salt than in the case of lactate one. This behaviour may be atribuited to the anion salt type.

According to Codină et al.  [27],  the  same  le- vel of iron ions addition contains lactate anion in a less amount that the gluconate anion. This will lead  to  a more compacted dough in the case of gluconate salt than in the case of lactate one. It is well known fact that the cation salt has a less effect on wheat flour components of dough system than the anion salt. As Miller and Ho- seney reported [28], anion from a salt added in wheat flour might decrease electrostatic repulsion between glu- ten proteins, allowing them to connect and thus forming more stable dough. An increase in the dough stability with the increase in the level of iron salts has also been repo- rted by Akhtar et al. and Rebellato et al. [29, 30].

The degree of softening values at 10 min decreased to a larger extent in the case of ferrous lactate than in the case of ferrous gluconate, which indicated a more wea- kening effect when lactate salt was incorporated in the wheat flour dough.

The dough viscometric rheological properties on Fal- ling Number and Amylograph values are shown in Fig. 1. The value decreased with the increase in level of iron

 

 

FN

Подпись: FN

Tg

Подпись: Tg

Tmax

Подпись: TmaxBox plot (FN)                                                 Box plot (Tg)                                                  Box plot (Tmax)

 

 

                                             

 

    1. (b)                                                                     (c)

 

Fig. 1. Dough viscometric rheological parameters with different types and amounts of iron ions addition: (a) FN = falling number, s;

 

    1. T = gelatinization temperature; (c) T
 

= temperature at peak viscosity.

 

g                                                                                     max

 

 

 

salts, with no significant differences between the dough samples with different types of iron ions incorporated (Fig. 1a). These decreased values indicated an increase in the wheat flour slurry viscosity, which could be correla- ted to decreased α-amylase activity in the wheat flours samples [31]. Falling number values  increased  up  to 413 s and the mean values of the samples were slightly higher than 330 s. This indicated that the flour with iron ions additions showed a low α-amylase activity, which agreed well with the results obtained in [32].

All the parameters in the experimental samples ana- lysed by Amylograph presented higher or similar values compared to the control sample (Fig. 1b and c). However, no significant difference were noticed between the sam- ples with different type of iron salt addition. These results were somewhat predictable due to the fact that the Amy- lograph device was also a viscometric method which could be used to predict the α-amylase activity of wheat flour [27, 33] which is highly connected with these pa- rameters. A lower α-amylase activity in wheat flour led to a lower starch hydrolysis and therefore to a lower amount of simple sugars and dextrins [34], which in turn caused an increase in all Amylograph parameters values [35].

Dough rheological properties during fermentation was analysed by a Chopin Rheofermentometer (Table 2). The maximum height of gaseous production were re- corded by a Rheofermentometer pressure sensor, and the

total CO2 volume production were determined by means of a pneumatic circuit which measured an increase in the pressure of the fermentation gases. The iron salts addi-

 

pable to retain the gas formed. Similar results were alo obtained by Codină et al. [26]. The maximum height of gaseous production (H’m) varied with the increase in level of iron ions addition. This was probably due to the fact that iron ions additions in increased amounts ini- tiated an increased gas production in the dough, but the wheat flour dough was not capabale to retain it.

(a)

Fig. 2 shows effects of the iron ions additions from the two types of salts on the storage/elastic module G’ and the loss/viscous module values G”. All the experi- mental dough samples, as expected, presented G’ > G” at all frequency ranges, which indicated a solid elas- tic-like behavior of wheat flour dough according to [36]. The G’ and G” values increased slightly with the in- crease in frequency from 1 to 20 Hz. The dough samples with 3 mg of iron ions addition showed a decrease in the G’ and G”, which implied that the samples demonstrated visco-elasticity characteristics to less extent than the con- trol sample. However, high levels of iron ions increased the G’ and G” values compared to the control sample. An explanation of this might be dehydration effect that iron salts could exert on gluten network that  might lead

 

 

2

 
tion increased the total CO

volume production from the

 

dough system, which was probably due to the fact that iron ions stimulated the growth of yeast cells and there-

 

2

 
fore the total amount of the CO

volume production.

 

However, the volume of the gas retained in the dough at the end of the test (VR) and the retention coefficient (CR) decreased with the increased level of iron ions ad- dition. This increase was greater in for the samples with ferrous lactate salt than for those with ferrous gluconate. The cause of that might be weakening effect that iron salts exerted on the wheat flour dough which was not ca-

 

Table 2. Effects of iron ions from the gluconate and lactate salt on Rheofermentometer rheological properties

 

Iron ions addition, mg per 100 g/salt type

H’m, mm

VT, ml

VR, ml

CR, %

0 (control)

30.8 ± 0.02

1,400 ± 0.2

1,074 ± 0.2

76.7 ± 0.2

3/FG

30.1 ± 0.01

1,415 ± 0.3

1,051 ± 0.3

74.3 ± 0.3

4/FG

32.0 ± 0.01

1,504 ± 0.4

1,023 ± 0.4

68.1 ± 0.4

5/FG

30.6 ± 0.02

1,354 ± 0.2

860 ± 0.2

63.5 ± 0.2

3/FL

31.1 ± 0.02

1,424 ± 0.3

975 ± 0.2

68.4 ± 0.3

4/FL

30.6 ± 0.01

1,450 ± 0.2

989 ± 0.1

68.3 ± 0.2

5/FL

31.0 ± 0.02

1,198 ± 0.4

736 ± 0.2

61.4 ± 0.3

Note: 0 is the sample without iron ions; FG is ferrous gluconate; FL is

ferrous lactate; H’m is maximum height of gaseous production; VT is

 

 

 

 

 

 

(b)

 

Fig. 2. Evaluation with frequency at 20°C of storage modulus G’ values (represented by solid symbols)  and loss modulus G” (open symbols) for samples with

different amounts of iron ions addition: 0 mg/100 g (●),

 

2

 
total CO

volume production; VR is volume of the gas retained in the

 

3 mg/100 g (▼), 4 mg/100 g (▲) and 5 mg/100 g (■)

 

dough at the end of the test; CR is retention coefficient (%)

 

from lactate salt (FL) (a) and gluconate salt (FG) (b)

 

 

         

    1. (d)

PC1

Подпись: PC1Fig. 3. Evaluation with temperature of storage modulus G’ values (represented by solid symbols) and loss modulus G” (open sym- bols for dough samples during heating with different amounts of iron ions addition: 0 mg/100 g (●), 3 mg/100 g (▼), 4 mg/100 g (▲) and 5 mg/100 g (■) from lactate salt (FL) (c) and gluconate salt (FG) (d)

 

 

PC2

 

2

Fig. 4. Principal component analysis of dough sample characteristics (amounts of iron ions from gluconate (FG) and lactate salt (FL) were 3, 4, and 5 mg/100 g) analyzed from the Farinograph and Rheofermentometer devices. WA =  water absorption; DT = dough development time; ST = stability; DS = degree of softening at 10 min; H’m = maximum height of gaseous production; VT = total CO  volume production; VR = volume of the gas retained in the dough at the end of the test; CR = retention coefficient, %.

 

 

to a more compacted dough with higher visco-elasticity properties.

The influence of the iron ions addition on dynamic moduli during heating is shown in Fig. 3. G’ and G” va- lues were lower in the samples with the maximum amount of iron ions (5 mg/100 g). It seemed that both ferrous lactate and ferrous glucanate displayed a significant ef- fect during dough heating. At the begining of heating the moduli decreased for all the samples due to protein dena- turation which seemed to increase with the increase in the amount of iron ion addition. Thus, proteins lost their ca- pacity to retain water, starch granules began to absorb the water and to gelatinise as temperature increased. This fact

is obvious, since an increase in dough elasticity and vis-

 

cosity is manifasted in the increase of the G’ and G” after the temperature exceeds 50°C.

The principal components analysis (PCA) of the wheat fl dough rheological characteristics determined by the Farinograph and Rheofermentometer is shown in Fig. 4. The two plots represent 99.72% of the total variance. The plot of PC1 vs. PC2 loadings shows a close association be- tween the dough sample with 3 mg of iron ions from the lactate salt addition and the volume of the gas retained in the dough at the end of the test (VR). The dough samples with 3 mg/100 g addition from gluconate salt is closed po- sitioned to the retention coeffi        (CR). This facts shows

that the samples with iron ions addition in the aount of

 

 

 

3 mg/100 g presents a prositive effect on the dough rheo- logical properties during the fermentation process.

The second PC axis show a close association between the samples with 4 mg of the iron ions per 100 g of the wheat flour, which indicate that both types of salts at this amount have a similar effect on dough rheological properties. However, both ferrous lactate and ferrous glu- conate in an increased amounts show a different effect, from a statistical point of view, on the dough rheologi- cal properties, since they are differently positioned in the PCA plot.

According to the dought rheological properties results obtained with the help of Farinograph and Rheofermen- tometer devices, good correlation may be observed be- tween CR and DS, CR and DT, ST and VR, as well as between VT and VR Rheofermentometer values.

 

CONCLUSION

The effect of iron ions from lactate and gluconate salts in amounts of 3, 4, and 5 mg/100 g on wheat flour dough empirical and fundamental rheological  proper- ties was analyzed. It seems that the 3 mg/100 g iron ions addition did not affect  adversely  the  dough  rheologi- cal properties since dough stability, dough development

time, and total CO2  volume production increased. In ad- dition, such dough rheological properties as the degree

 

of softening at 10 min, Amylopgrah paramter values, volume of the gas retained in the dough at the end of the test, retention coefficient, and dynamic rheological pro- perties did not decrease significantly. The 4 mg/100 g the iron ions addition weakened the dough rheological pro- perties, namely decreased dough stability, the degree of softening at 10 min, and the retention coefficient value. Despite the increase of the total CO volume production, the wheat flour dough was not capable of retaining a high amount of CO  released.

2

 

2

However, the 5 mg/100 g iron ions addition impaired the dough rheological properties in the case of lactate salt more significantly than in the case of gluconate salt. According to the data obtained, ferrous gluconate in the amount of up to 4 mg/100g was optimal to use in bread making wheat flour to ensure good rheological properties of dough.

 

CONFLICT OF INTEREST

The authors declare no conflict of interest.

 

ACKNOWLEDGEMENTS

This work was supported by a grant of the Roma- nian National Authority for Scientific Research and In- novation. CNCS/CCCDI – UEFISCDI. project number PN-III-P2-2.1-BG-2016-0079. within PNCDI III.

 

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