DOI: https://doi.org/10.21323/2414-438X-2021-6-2-135-140
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Available online at https://www.meatjournal.ru/jour Original scientific article
TECHNO-FUNCTIONAL, TEXTURAL AND SENSORIAL PROPERTIES OF FRANKFURTERS AS AFFECTED BY THE ADDITION OF BEE POLLEN POWDER
Received 26.04.2021 Accepted in revised 27.05.2021 Accepted for publication 10.06.2021
Sasa M. Novakovic, Ilija V. Djekic, Mirjana B. Pesic, Aleksandar Z. Kostic, Danijel D. Milincic, Igor B. Tomasevic*
University of Belgrade, Faculty of Agriculture, Belgrade, Serbia
Keywords: texture, sensory, Warner-Bratzler, emulsion, FTIR-ATR Abstract
The objective of this study was to determine whether the addition of different pollen powder concentrations (0.5; 1.0 and 1.5 g/100 g) had an influence on techno-functional, textural and sensorial traits of frankfurters. Examining the techno-func-tional characteristics of pollen, a conclusion was reached that the higher the concentration, the higher the emulsification and better techno-functional properties. Also, FTIR-ATR analysis has shown that specific pollen molecules provided good emulsifying properties of sausages. On the other hand, sensory analysis showed that sausages with the addition of 1.0% and 1.5% of pollen powder have a more pronounced floral odor. Warner-Bratzler shear force test has shown that the incorporation of pollen caused a more stable product throughout sixty days of storage than the control sample. It could be explained by the formation of more protein-protein interactions due to the addition of non-meat proteins in the formulation of frankfurters and obtaining a more stable product than the control one. All things considered, it can be concluded that pollen exhibits good techno-functional properties and could be utilized in the formulation of frankfurters with improved and steady techno-functional properties during two months of refrigerated storage.
Introduction
The most common type of emulsified meat products in the world are frankfurters [1]. The world leader in the number of different varieties and the birthplace of frankfurters is Germany. Their popularity is reflected by the convenience in preparation, tastefulness and time-saving. The wide variety in physicochemical properties of emulsions is affected by the diversity of components used during technological process of the production of sausages. Emulsions, also called meat batters, are a complex mix of different systems of dissolved proteins and salts, suspensions, gels made from myofibrillar proteins and emulsions that contain stabilized fat in a gel and fat which is partially present in liquid form [2].
One of the most important quality parameters of the emulsified meat products, such as frankfurters, is emulsion stability. It is highly dependant on the amount of fat and water, as well as myofibrillar proteins, previously extracted from the muscle tissue. Mechanical energy from cutter knives destroys sarcolemma and additives such as nitrite salt and phosphates and activate the protein released. The solubilized protein simultaneously immobilizes the water and emulsifies the added fat, stabilizing them in a tridimensional matrix [2].
Nowadays, there is a growing concern in the meat industry to produce healthier products and to change the perception of them as being unhealthy. Thus, many natural additives such as mushroom decoctions [3,4], mixed extracts of green tea, olive leaves and stinging nettle [5], garlic extract [6], are used for the production of sausages, in order to partially or totally replace the use of commer-
cial antioxidants. Two key processes take a part in this technology: reformulation, by the reduction of ingredients that some consumers perceive as unhealthy (commercial antioxidants, nitrites and sodium chloride) and enriching the product with highly nutritious compounds that consumers perceive as health-beneficial. However, the question arises how these extracts affect the texture, techno-functional (emulsifying) and sensory properties of sausages.
Pollen is a natural product that contains a high amount of nutrients and bioactive compounds, such as polyphenols and flavonoids [7], which give it excellent antioxidant activity. Pollen, as a multi-component natural product, contains significant quantities of proteins, carbohydrates and lipids. These constituents give pollen good emulsifying, foaming and gelling properties [7,8]. Therefore, this complex structure of pollen allows its application in the formulation of numerous food products. Until now, several food products such as yogurt [9], cheese [10], bread [11], etc. have been enriched with pollen. Additionally, it is known that lyophilized pollen polyphenol extracts have been added to sausages [12], as well. However, to the best of our knowledge, it has never been investigated before how pollen powder affects the texture and sensory properties of meat products. Unlike pollen polyphenol extract, which has only antioxidant potential, pollen powder as a multi-component system can have a multifunctional impact in the production of high-fat products such as frankfurters.
Therefore, the objective of this research was to characterize bee pollen powder and frankfurters containing
FOR CITATION: Novakovic, S.M., Djekic, I.V., Pesic, M.B., Kostic, A.Z., Milincic, D.D., Tomasevic, I. B., (2021). Techno-functional, textural and sen-
sorial properties of frankfurters as affected by the addition of bee pollen powder. Theory and practice of meat processing, 6(2), 135-140. https://doi.org/10.21323/2414-438X-2021-6-2-135-140
it using FTIR-ATR. Also, this study aimed to investigate techno-functional properties of pollen in three different concentrations and to determine the influence of pollen addition on the textural and sensorial traits of the final product.
Objects and methods
Bee-collected pollen (hereafter referred as pollen) was purchased from local beekeepers situated in East Serbia. According to the producers' declaration, the pollen predominantly originated from rapeseed (Brassica napus) and ash tree (Fraxinus spp.).
Techno-functional properties of pollen
Techno-functional properties such as emulsifying and foaming properties, as well as water/oil absorption capacity (WAC/OAC) were determined according to the methods previously described by [13]. Both, emulsifying and foaming properties were determined for three different pollen concentration (0.5; 1; 1.5 g/100 g aqueous dispersion of pollen sample at pH 7) at which pollen was added to Frankfurter-type sausages.
Frankfurter's formulations
Sausages were manufactured in a commercial meat factory (BigBull Foods, Bacinci, Serbia). Fresh pork meat (Biceps femoris), without connective tissue, pork back fat and ice were used in the amounts of 50%, 25% and 25%, respectively. Meat was transferred to a bowl chopper, and salt and polyphosphate were added. After that, meat tissue was comminuted for 3 minutes at low speed, in order to extract myofibrillar proteins until the temperature reached 6 °C, when other ingredients were slowly added. The temperature of the mixture was not allowed to exceed 12 °C [14]. Pollen is added in the amount of 0.5% (T1), 1.0% (T2) and 1.5% (T3). Each treatment was repeated in triplicate, as well as a control sample, only without pollen in its formulation. These mixtures were blended until they reached 12 °C. After preparation of emulsions, sausages were stuffed into polyamide casings (Edicas, Girona, approximate 22 mm diameter) and cooked at 80 °C in a smokehouse (EL-C-Q 1900, Kerres Anlagenststeme GmbH, Backnang, Germany) until the core temperature of 72 °C. The cooked samples were cooled using the shower and placed in vacuum bags (4 frankfurters approximately 50g each) and coded according to appropriate treatment production.
FTIR-ATR analysis
FTIR-ATR spectra of pollen powder and small portions of frankfurters enriched with pollen were recorded by using an ALPHA FTIR spectrophotometer (Bruker) equipped with a Platinum ATR diamond module. The FT-IR-ATR recording parameters were as follows: the spectral resolution was 4cm-1; 32 scans; absorbance mode was in the range of 400 to 4000 cm-1. Date collection and analysis were performed using OPUS7.5 software.
Warner-Bratzler Shear force measurement
Textural properties of frankfurters were conducted using Warner-Bratzler Shear force (WBSF) test [15]. For the purpose of the investigation through this method, Warner-Bratzler 'V' slot blade was attached to the Universal testing machine (TA.XT Stable Micro System Corporation, UK). The load cell capacity was 50 kg, while shearing speed was 1.50 mm sec-1. The parameter obtained in this method was the maximum shear force (N) and represents the highest peak of the curve, which is the maximum resistance of the sample to shearing. At least six specimens were tested from each sample (about 24 per one treatment). All analyses were done in triplicate.
Sensorial traits of frankfurters
Five trained and experienced panel members were selected to participate in the development of sensory profiles for the three different concentrations of pollen in frankfurters. They were chosen based on their ability to provide similar responses on repeated occasions, smell acuity, interest in the project and availability for the duration of the study. In order to ensure that panelists were not influenced in any way, no information with regard to the nature of the samples was provided. Panelists were reminded not to use perfumed cosmetics and to avoid exposure to foods and/or fragrances at least 30 min before evaluation sessions.
A 100-point category scale was used to measure the intensity of each sensory attribute (pork flavour, sweet, floral, woody, salty, juicy) for the different concentrations of pollen in frankfurters. One (1) on the category scale denoted the total absence of sensory attribute (e. g., no floral aroma), fifty (50) denoted a moderate presence and one hundred (100) denoted the most intense condition (e. g., extremely floral frankfurter aroma).
Frankfurters were sliced into 25-mm slices and coded with a random three-digit code. The serving temperature was 40 °C. One frankfurter was served at a time. When served to the panel, a coded sample was placed on a white plastic tray. Care was taken to ensure uniformity of each sample (volume served and serving temperature) and both replication of the different samples. Samples were randomized to exclude any bias due to the position effect. Acquisition of evaluation scores and data analysis was performed by Smart Senso Box software (Smart Sensory Solutions S.r.l., Sassari, Italy). Panel members were provided with water at room temperature, toasted bread and apples, which served as palate cleansers in between evaluation sessions.
Statistical analysis
Statistical analysis software SPSS17.0 (Chicago, Illinois, USA) was used for data analysis. Data from techno-func-tional properties, FTIR and sensorial traits of frankfurters were tested using One-Way Anova, while textural characteristics were performed using Two-Way Anova with repeated measurements, considering treatments and storage
as fixed effects and replicate as a random effect. Significant differences (P < 0.05) between means were determined by Tukey's HSD post-hoc test.
Results and discussion
Techno-functionalproperties of pollen
Emulsions and foams are usually crucial in the formation of texture and taste of food. Therefore, the potential application of pollen as a functional ingridient in different food products requires the identification of its techno-functional properties (Table 1). The values obtained for the emulsifying stability index (ESI) ranged from 14.04 min to 11.53 min, whereas emulsifying activity index (EAI) varied from 58.59 to 156.60 m2/g, that depending on the pollen concentration in aqueous dispersion. All pollen aqueous dispersions exhibited the complete absence of the ability to form stable foams. The observed characteristic confirmed the anti-foaming properties of pollen, which is in accordance with a previous report from [13]. The oil and water absorption capacities of analysed pollen were 1.5 and 0.9 g/g, respectively, which is in line with results reported by [13]. It can be concluded that pollen possesses excellent emulsifying properties, oil and water absorption capacities, which qualify it for application in meat products, primarily in heterogeneous colloidal products such as Frankfurtertype sausages where these features are desirable.
Table 1. Techno-functional properties of pollen sample
Techno-functional properties
Emulsifying properties Foaming properties Water/Oil absorption capacity
ESI (min) EAI (m2/g) FS (%) FC (%) WAC (g/g) OAC (g/g)
14.04 ± 1.66 11.53 ± 0.33 12.93 ± 0.26
58.59 ± 10.70 112.26 ± 8.24 156.60 ± 21.87
n.d. n.d. n.d.
n.d. n.d. n.d.
9.1 ± 0.2 8.5 ± 0.1
* "n.d." — not detected; The results in the table are presented as means ± standard deviations (mean ± SD; n=3); Abbreviations: ESI — emulsion stability index; EAI — emulsion activity index; FS — foam stability; FC — foam capacity; WAC — water absorption capacity; OAC — oil absorption capacity
FTIR-ATR analysis
FTIR-ATR spectra of frankfurters and pollen-enriched frankfurters show the same absorption bands that mainly correspond to proteins, lipids and water (Figures 1a, b, c, d). The broad band at 3272 cm-1 corresponding to O-H stretching vibrations which are most likely originated from water, because the ratio of added ice during the production of frankfurters was as much as 25%. Vibrations observed in the FTIR spectrum at 2960 cm-1; 2920-2924 cm-1 and 2852 cm-1 originated from CH3 asymmetric, CH2 asymmetric and CH2 symmetric stretching and mainly belong to lipids [16,17]. The strong and dominant peaks at 1650cm-1 (Amide I) and 1540cm-1 (Amide II) originated from C=O stretching, N-H bending and C-N stretching of proteins. Peak at 1736 cm-1 was corresponding to C=O carbonyl stretching which can be derived from cholesterol and tri-
acylglycerol esters [17]. Vibration at 1455 cm-1 represents C-O-H bending of lipids and proteins, while vibration at 1396 cm-1 can be linked with COO- symmetric stretching of fatty acids. Peak at 1240 cm-1 can be connected with PO2-asymmetric stretching indicating the presence of nucleic acids (mainly), phospholipids, phosphorylated proteins in the analyzed samples [16,17]. Vibrations at 1172 cm-1 may be derived from CO stretching vibration of C-OH groups of serine, threonine and tyrosine residues [16]. Peak at 1082 cm-1 can be correlated with PO2-symmetric stretching; C-O stretching and C-H deformation which was corresponding to the nucleic acids, phospholipids and glycogen [16,17].
Spectrum of pollen powder (Figure 1e), showed dominant peaks belonging to the region of 3000-2800 cm-1 (oil's regions); 1700-1500 cm-1 (protein region) and 1200-900 cm-1 (carbohydrate regions) [7,18,19]. A strong peak at 1025 cm-1 indicated the presence of polysaccharides, and less pronounced bands in the range of 700 to 900 cm-1 can originate from C-O-C and C-OH vibrations [7,20]. Broad band in the range of 1420-1370 cm-1 can originate from C-H deformation vibrations of lipids and cellulose, while region between 1350-1200 cm-1 can be connected with N-H deformation and C-H stretching of amide III [19,21]. In the spectra of pollen-enriched frankfurters (Figures 1b, c, d), bands originated from frankfurter were dominant, which in most of cases overlap bands originating from pollen. Thus, through this approach cannot be concluded whether there were strong chemical interactions between constituents of frankfurter and pollen or not.
Figure 1. FTIR-ATR spectre of: (a) frankfurters without pollen; (b) frankfurters with 0.5% pollen; (c) frankfurters with 1% pollen; (d) frankfurters with 1.5% pollen; (e) pollen powder
Warner-Bratzler shear force of sausages One of the main characteristics of meat products that influence consumers' purchasing decision is toughness/ tenderness [22]. Three different concentrations of pollen added did not cause a statistically significant difference (P > 0.05) between treatments, during 40 days of storage period, regarding Warner-Bratzler Shear force values (N). On the 60th day, significant difference (P < 0.05) was observed between control group and treatments with pollen (T1, T2, T3) (Table 2). Usually, the higher the non-meat protein content in sausages, the harder and chewier texture of sausages. In this case, pollen, as a natural ingredient, is rich in protein, but also in lipid content [13]. Hence, these components are crucial in the formation of emulsions, as well as the texture and taste of the final product.
Table 2. Warner-Bratzler Shear force of frankfurters
Storage time (days)
C T1 T2 T3
1 2.76 ± 0.18a, A 2.86 ± 0.07a, A 2.81 ± 0.15a, A 2.81 ± 0.16a, A
20 2.73 ± 0.17a, A 2.85 ± 0.2a, A 2.87 ± 0.17a, A 2.89 ± 0.16a, A
40 2.72 ± 0.17a, A 2.85 ± 0.2a, A 2.87 ± 0.17a, A 2.89 ± 0.16a, A
ib, A
3 60 2.24 ± 0.15a, B 3 ± 0.21b, A 3.04 ± 0.23b, A 3.14 ± 0.2b
1 Abbreviations: C = control group of frankfurters, without pollen; T1 = 0.5% pollen added in frankfurters; T2 = 1.0% pollen added in frankfurters; T3 = 1.5% pollen added in frankfurters; TBARS — Thiobarbituric acid reactive substances value.
2 Values are displayed as arithmetic means ± standard errors of means (mean ± SEM). Values with different lowercase letters (a-b) in the same row differ significantly (P < 0.05). Values with different uppercase letters (A-C) in the same column differ significantly (P < 0.05).
Throughout the period of storage, there was no statistically significant difference (P > 0.05) within treatments with the addition of pollen, while in the control group there was a significant (P < 0.05) decrease. Excellent emulsifying properties, oil and water absorption of pollen contribute to obtaining stable product throughout storage, especially when it comes to such a long period as two months are. Also, it is an indicator of the good stability of frankfurters
with pollen added during storage. However, although there were no statistical differences, a slight tendency toward an increase in the shear work appears with the longer storage period in treatments with pollen. A similar trend in the increase of WBSF values in sausages reported [23], as well as [24], who explained that this trend was the consequence of the moisture loss and the mechanism that favors hardening of the sausages, such as the formation of cross-links in proteins. In our study, it could be explained with the additional value of proteins added via pollen and more crosslinks formed throughout the storage period.
Sensorial traits of frankfurters
Pork flavor was defined as the amount of pork flavor identity. Major notes for pork flavor identity consist of roasted notes that round and fully aromatic and generally associated with pork fat that has been broiled. Bloody and serumy notes that are associated with blood of cooked meat and closely related to metallic aromatic are also present. Third major pork flavor note is liver-like and associated with cooked organ meat, mostly liver. Finally, pork flavor can be described with green-haylike notes (brown/ green dusty aromatic associated with dry grasses, hay, dry parsley and tea leaves) and umami notes (flat, salty, somewhat brothy with the taste of glutamate, salts of amino acids and nucleotides) [25]. Unsurprisingly, frankfurter samples without the addition of pollen were perceived by the panelists as samples with the most intense pork flavor aroma (70.5), while the pork flavor intensity was only mild for T1 samples (58) and moderate for T2 and T3 samples (48.1) (Figure 2).
Floral aroma was described as taste and smell associated with different flowers [26]. We can conclude that with the addition of pollen into frankfurters they have obtained floral notes that have not been present in control samples (12). As much as 0.5% of pollen increased the sensation of floral aroma by two fold (25) in T1 samples and were moderately perceived in both T2 (44) and T3 (45) samples. The fact that floral notes reached a plateau with the addition of 1% of pol-
woody juicy
• C #T1 OT2 OT3
Figure 2. Sensorial traits of frankfurters 1 Abbreviations: C = control group of frankfurters, without pollen; T1 = 0.5% pollen added in frankfurters; T2 pollen added in frankfurters.
1.0% pollen added in frankfurters; T3 = 1.5%
len is actually a good thing since the actual "taste" of flowers can be off-putting because, at the end of the day, people don't eat flowers that often. Food that is flavored with floral notes usually push too far. Florals are most pleasing to the palate when they are well balanced and offset by thick rich texture of food like the one present in frankfurters.
Conclusion
The incorporation of pollen resulted in obtaining a stable product during two months of chilled storage, without any adverse effect regarding textural characteristics.
Although excellent emulsifying properties of pollen were obtained, a certain limitation in terms of sensory properties occurs, especially due to obtaining specific notes that could provoke certain negative ratings from consumers. FTIR-ATR has shown a multi-component structure of pollen powder which provides good emulsifying properties to sausages and obtaining good consistency. All things considered, each pollen concentration could be used as a potential natural additive that contributes to obtaining a stable emulsion and consistent meat product during the two months of refrigerated storage.
REFERENCES
1. Fernández-López, J., Lucas-González, R., Viuda-Martos, M., Sayas-Barberá, E., Navarro, C., Haros, C. M., Pérez-Álvarez, J. A. (2019). Chia (Salvia hispanica L.) products as ingredients for reformulating frankfurters: Effects on quality properties and shelf-life. Meat Science, 156, 139-145. https://doi.Org/10.1016/j. meatsci.2019.05.028
2. Feiner, G. (2006). Meat products handbook: Practical science and technology. Elsevier.
3. Novakovic, S., Djekic, I., Klaus, A., Vunduk, J., Djordjevic, V., Tomovic, V. et. al. (2019). The Effect of Cantharellus Cibarius Addition on Quality Characteristics of Frankfurter during Refrigerated Storage. Foods, 8(12), Article 635. https://doi.org/10.3390/ foods8120635
4. Novakovic, S., Djekic, I., Klaus, A., Vunduk, J., Dordevic, V., Tomovic, V. et. al. (2020). Application of porcini mushroom (Boletus edulis) to improve the quality of frankfurters. Journal of Food Processing and Preservation, 44(8), Article e14556. https://doi. org/10.1111/jfpp.14556
5. Alirezalu, K., Hesari, J., Yaghoubi, M., Khaneghah, A. M., Ali-rezalu, A., Pateiro, M., Lorenzo, J. M. (2021). Combined effects of e-polylysine and e-polylysine nanoparticles with plant extracts on the shelf life and quality characteristics of nitrite-free frankfurtertype sausages. Meat Science, 172, Article 108318. https://doi. org/10.1016/j.meatsci.2020.108318
6. Horita, C. N., Farías-Campomanes, A. M., Barbosa, T. S., Es-merino, E. A., da Cruz, A. G., Bolini, H. M. A. et. al. (2016). The antimicrobial, antioxidant and sensory properties of garlic and its derivatives in Brazilian low-sodium frankfurters along shelf-life. Food Research International, 84, 1-8. https://doi.org/10.1016/j. foodres.2016.02.006
7. Kostic, A., Milincic, D., Barac, M., Ali Shariati, M., Tesic, Z., Pesic, M. (2020). The Application of Pollen as a Functional Food and Feed Ingredient — The Present and Perspectives. Biomole-cules, 10(1), Article 84. https://doi.org/10.3390/biom10010084
8. Thakur, M., Nanda, V. (2020). Exploring the physical, functional, thermal, and textural properties of bee pollen from different botanical origins of India. Journal of Food Process Engineering, 43(1), Article e12935. https://doi.org/10.1111/jfpe.12935
9. Karabagias, I. K., Karabagias, V. K., Gatzias, I., Riganakos, K. A. (2018). Bio-Functional Properties of Bee Pollen: The Case of "Bee Pollen Yoghurt". Coatings, 8(12), Article 423. https://doi. org/10.3390/coatings8120423
10. Abd Elhamid, A. M., Elbayoumi, M. M. (2017). Influence of bee pollen on the bioactive behavior, sensory and physicochemical properties of white cheese made from camel and cow milk mixture. Journal of Food Dairy Sciences, 8(11), 419-424.
11. Di Cagno, R., Filannino, P., Cantatore, V., Gobbetti, M. (2019). Novel solid-state fermentation of bee-collected pollen emulating the natural fermentation process of bee bread. Food Microbiology, 82, 218-230. https://doi.org/10.1016Zj.fm.2019.02.007
12. de Florio Almeida, J., dos Reis, A. S., Heldt, L. F. S., Pereira, D., Bianchin, M., de Moura, C. et. al. (2017). Lyophilized bee pollen extract: A natural antioxidant source to prevent lipid oxidation in refrigerated sausages. LWT-FoodScience Technology, 76, 299305. https://doi.org/10.1016/j.lwt.2016.06.017
13. Kostic, A., Barac, M., Stanojevic, S., Milojkovic-Opsenica, D., Tesic, Z., Sikoparija, B. et. al. Physicochemical composition
and techno-functional properties of bee pollen collected in Serbia. LWT-Food Science Technology, 62(1), 301-309. https://doi. org/10.1016/j.lwt.2015.01.031
14. Costa-Lima, B. R. C., Canto, A. C. V. C. S., Suman, S. P., Conte-Junior, C. A., Silveira, E. T. F., Silva, T. J. P. (2014). Sex-specific effect of ractopamine on quality attributes of pork frankfurters. Meat Science, 96(2, Part A), 799-805. https://doi. org/10.1016/j.meatsci.2013.10.001
15. De Huidobro, F. R., Miguel, E., Blázquez, B., Onega, E. (2005). A comparison between two methods (Warner-Bratzler and texture profile analysis) for testing either raw meat or cooked meat. Meat Science, 69(3), 527-536. https://doi.org/10.1016/j.meat-sci.2004.09.008
16. Candogan, K., Altuntas, E. G., igci, N. (2021). Authentication and Quality Assessment of Meat Products by Fourier-Transform Infrared (FTIR) Spectroscopy. Food Engineering Reviews, 13(1), 66-91. https://doi.org/10.1007/s12393-020-09251-y
17. Deniz, E., Güne§ Altunta§, E., Ayhan, B., igci, N., Ózel Demiralp, D., Candogan, K. (2018). Differentiation of beef mixtures adulterated with chicken or turkey meat using FTIR spectroscopy. Journal of Food Processing Preservation, 42(10), Article e13767. https://doi.org/10.1111/jfpp.13767
18. Andrade, J., Pereira, C. G., de Almeida Junior, J. C., Viana, C. C. R., de Oliveira Neves, L. N., da Silva, P. H. F. et. al. (2019). FTIR-ATR determination of protein content to evaluate whey protein concentrate adulteration. LWT, 99, 166-172. https://doi. org/10.1016/j.lwt.2018.09.079
19. Kasprzyk, I., Depciuch, J., Grabek-Lejko, D., Parlinska-Wojtan, M. (2018). FTIR-ATR spectroscopy of pollen and honey as a tool for unifloral honey authentication. The case study of rape honey. Food Control, 84, 33-40. https://doi.org/10.1016/j.food-cont.2017.07.015
20. Kostic, A. Z., Milincic, D. D., Gasic, U. M., Nedic, N., Stanojevic, S. P., Tesic, Z. L., Pesic, M. B. (2019). Polyphenolic profile and an-tioxidant properties of bee-collected pollen from sunflower (Heli-anthus annuus L.) plant. LWT, 112, Article 108244. https://doi. org/10.1016/j.lwt.2019.06.011
21. Kostic, A. Z., Milincic, D. D., Stanisavljevic, N. S., Gasic, U. M., Levic, S., Kojic, M. O. at al. (2021). Polyphenol bioaccessibility and antioxidant properties of in vitro digested spray-dried thermally-treated skimmed goat milk enriched with pollen. Food Chemistry, 351, Article 129310. https://doi.org/10.1016/j.food-chem.2021.129310
22. Jin, S.-K., Choi, J. S., Yang, H.-S., Park, T.-S., Yim, D.-G. (2018). Natural curing agents as nitrite alternatives and their effects on the physicochemical, microbiological properties and sensory evaluation of sausages during storage. Meat Science, 146, 3440. https://doi.org/10.1016/j.meatsci.2018.07.032
23. Silva, F. A. P., Amaral, D. S., Guerra, I. C. D., Arcanjo, N. M. O., Bezerra, T. K. A., Ferreira, V. C. S. et. al. (2014). Shelf life of cooked goat blood sausage prepared with the addition of heart and kidney. Meat Science, 97(4), 529-533. https://doi.org/10.1016/j. meatsci.2014.03.018
24. Herrera, E. A. C. (2006). Contributions to the characterization of the black pudding of León and evolution of certain physical, chemical and microbiological parameters during its conservation under refrigeration.(theses of the dissertation) (In Spanish)
25. Miller, R. K. (2012). Sensory Evaluation of Beef Flavor. Chapter in a book: Handbook of Meat, Poultry and Seafood Quality (pp. 173-191). Blackwell Publishing Ltd.
26. Galán-Soldevilla, H., Ruiz-Pérez-Cacho, M. P., Serrano Jiménez, S., Jodral Villarejo, M., Manzanares, A. B. (2005). Develop-
ment of a preliminary sensory lexicon for floral honey. Food Quality and Preference, 16(1), 71-77. https://doi.org/10.1016/ j.foodqual.2004.02.001
AUTHOR INFORMATION
Sasa M. Novakovic — PhD candidate, MSc, teaching assistant, Animal Source Food Technology Department, Faculty of Agriculture, University of Belgrade. 6 Nemanjina, Zemun, 11080, Belgrade, Serbia. E-mail: sasha.novakovic@agrif.bg.ac.rs ORCID: https://orcid.org/0000-0002-0292-195X
Ilija V. Djekic — PhD, full professor, full professor, Department for Food Safety and Quality Management, Faculty of Agriculture, University of Belgrade. 6 Nemanjina, Zemun, 11080, Belgrade, Serbia. E-mail: idjekic@agrif.bg.ac.rs ORCID: https://orcid.org/0000-0002-8132-8299
Mirjana B. Pesic — PhD, associate professor, associate professor, Department for Chemistry and Biochemistry, Faculty of Agriculture, University of Belgrade. 6 Nemanjina, Zemun, 11080, Belgrade, Serbia. E-mail: mpesic@agrif.bg.ac.rs ORCID: https://orcid.org/0000-0001-9779-1686
Aleksandar Z. Kostic — PhD, assistant professor, Department for Chemistry and Biochemistry, Faculty of Agriculture, University of Belgrade. 6 Nemanjina, Zemun, 11080, Belgrade, Serbia. E-mail: akostic@agrif.bg.ac.rs ORCID: https://orcid.org/0000-0002-1012-4029
Danijel D. Milincic — PhD candidate, MSc, teaching assistant, Department for Chemistry and Biochemistry, Faculty of Agriculture, University of Belgrade. 6 Nemanjina, Zemun, 11080, Belgrade, Serbia. E-mail: milincic93@gmail.com ORCID: https://orcid.org/0000-0002-2476-9426
Igor B. Tomasevic — PhD, associate professor, associate professor, Animal Source Food Technology Department, Faculty of Agriculture, University of Belgrade. 6 Nemanjina, Zemun, 11080, Belgrade, Serbia. E-mail: tbigor@agrif.bg.ac.rs ORCID: https://orcid.org/0000-0002-1611-2264 * corresponding author
All authors bear responsibility for the work and presented data. All authors made an equal contribution to the work.
The authors were equally involved in writing the manuscript and bear the equal responsibility for plagiarism. The authors declare no conflict of interest.