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Lactoferrin's potential application in enhancing yoghurt's microbial and sensory qualities, with emphasis on the starter culture activity

Published online by Cambridge University Press:  08 January 2024

Walaa G. Nadi*
Affiliation:
Department of Food Hygiene and Control, Faculty of Veterinary Medicine, Cairo University, 12211, Giza, Egypt
Eman M. Taher
Affiliation:
Department of Food Hygiene and Control, Faculty of Veterinary Medicine, Cairo University, 12211, Giza, Egypt
Abeer Abdel Nasser Awad
Affiliation:
Department of Food Hygiene and Control, Faculty of Veterinary Medicine, Cairo University, 12211, Giza, Egypt
Lamiaa Ibrahim Ahmed
Affiliation:
Department of Food Hygiene and Control, Faculty of Veterinary Medicine, Cairo University, 12211, Giza, Egypt
*
Corresponding author: Walaa G. Nadi; Email: walaa.gamal@vet.cu.edu.eg
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Abstract

This research paper aimed to examine the antibacterial activity of lactoferrin (LF) as a potential natural alternative in the dairy sector, by measuring its minimum inhibitory concentration (MIC) against a number of common food-borne pathogens as well as Pseudomonas aeruginosa, one of the major dairy product spoiling microorganisms. Additionally, a viability experiment was applied to laboratory-manufactured set yoghurt to assess its impact on the activity of starter culture, sensory properties and STEC survivability. The findings demonstrated that LF exhibited significant antimicrobial activity, particularly against E. coli and S. typhimurium with MIC values of 0.0001 and 0.01 mg/ml, respectively. However, P. aeruginosa and B. cereus were quite resistant to LF requiring higher concentrations for MIC (2.5 mg/ml). By the third day of storage, LF at 0.0001 and 0.001 mg/ml significantly reduced the survivability of Shiga toxin-producing E. coli STEC by 70 and 91.6%, respectively, in the lab-manufactured yoghurt. Furthermore, LF enhanced the sensory properties of fortified yoghurt with a statistically significant difference in comparison to the control yoghurt group. There was no interference with the activity of the starter culture throughout the manufacturing process and the storage period. In conclusion, the potent antimicrobial effect of LF opens a new avenue for the dairy industry's potential applications of LF as a natural preservative without negatively influencing the sensory properties and starter culture activity of fermented products.

Type
Research Article
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of Hannah Dairy Research Foundation

Despite significant advances in food safety research, foodborne illnesses continue to be one of the major public health concerns that lead to global morbidity and mortality (Jenkins et al., Reference Jenkins, Bird, Wensley, Wilkinson, Aird, MacKintosh, Greig, Simpson, Byrne, Wilkinson, Godbole, Arunachalam and Hughes2022). Food poisoning and intoxication happen despite the application of several food preservation measures during dairy production processes as a result of microbial growth and their potential toxin production (Gonelimali et al., Reference Gonelimali, Lin, Miao, Xuan, Charles, Chen and Hatab2018; Quinto et al., Reference Quinto, Caro, Villalobos-Delgado, Mateo, De-Mateo-silleras and Redondo-Del-río M2019). In the United Kingdom, there were an estimated 2.4 million instances of food-borne gastroenteritis in 2018, with 16 300 cases requiring hospitalization and more than 180 deaths (Jenkins et al., Reference Jenkins, Bird, Wensley, Wilkinson, Aird, MacKintosh, Greig, Simpson, Byrne, Wilkinson, Godbole, Arunachalam and Hughes2022). S. aureus, E. coli, Salmonella species, and B. cereus are the most prevalent microorganisms isolated in the previous studies (Abdel-Salam and Soliman, Reference Abdel-Salam and Soliman2019; Atia et al., Reference Atia, Mohamed, Abo ElRoos and Awad2020; Adam et al., Reference Adam, Aly and Saad2021; Halim et al., Reference Halim, El-Essawy, Awad, El-Kutry and Ahmed2022; Taher et al., Reference Taher, Valtman and Petrovski2022; Nadi et al., Reference Nadi, Ahmed, Awad and Taher2023). In addition, P. aeruginosa is the leading cause of spoiled dairy products; it releases thermo-tolerant proteolytic and lipolytic enzymes that impact dairy product quality and shelf life (Eleboudy et al., Reference Eleboudy, Amer, Nasief and Eltony2015; Ahmed et al., Reference Ahmed, Ibrahim, Abdel-Salam and Fahim2021). Food-borne illnesses linked to yoghurt consumption have been reported in many countries (Cutrim et al., Reference Cutrim, Barros, Franco and Cortez2017). Contamination of yoghurt with pathogens occurs mainly because of the use of raw milk, improper processing, inadequate thermal treatment, post-processing contamination, mishandling and poor sanitation programs (Salih et al., Reference Salih, Abdullahi and Al Taweel2018; Atia et al., Reference Atia, Mohamed, Abo ElRoos and Awad2020; Taher et al., Reference Taher, Hemmatzadeh, Aly, Elesswy and Petrovski2020; Adam et al., Reference Adam, Aly and Saad2021; Nadi et al., Reference Nadi, Ahmed, Awad and Taher2023).

Natural preservatives are expected to become a more popular alternative to synthetic ones for ensuring food safety (Rybarczyk et al., Reference Rybarczyk, Kieckens, Vanrompay and Cox2017; Quinto et al., Reference Quinto, Caro, Villalobos-Delgado, Mateo, De-Mateo-silleras and Redondo-Del-río M2019). Lactoferrin (LF) is a promising antibacterial compound that has recently been used against foodborne pathogens in the food industry (Ombarak et al., Reference Ombarak, Saad and Elbagory2019). LF is an 80 kDa multifunctional iron-binding glycoprotein, a member of the transferrin family, found naturally in exocrine secretions such as milk, saliva, tears, serum and the granules of neutrophilic polymorph nuclear leukocytes (Niaz et al., Reference Niaz, Saeed, Ahmed, Imran, Maan, Khan, Tufail, Anjum, Hussain and Suleria2019). Its concentration in milk ranges from 0.02 to 0.20 mg/ml (Taha et al., Reference Taha, El barbary, Ibrahim, Mohammed and Wahba2019). It was first included in infant formula in 1986 and has subsequently been utilized in a wide range of products like toothpaste, food supplements and cosmetics (Taha et al., Reference Taha, El barbary, Ibrahim, Mohammed and Wahba2019; Wang et al., Reference Wang, Timilsena, Blanch and Adhikari2019). Consumer acceptance of LF has steadily increased in recent years following its approval as a food ingredient by the FDA in 2000 and the European Commission in 2012 (Franco et al., Reference Franco, Pérez, Conesa, Calvo and Sánchez2018). Additionally, LF is purported to have antiviral, anticancer, antioxidant, anti-inflammatory and cell growth-promoting actions, and enhances the growth of the commensal probiotic in the gut microbiome (Kell et al., Reference Kell, Heyden and Pretorius2020). The antibacterial activity of LF has been explained by two mechanisms; (i) iron-dependency, by depletion of the microorganism's main food source, iron and (ii) iron-independent, where both Gram-negative lipopolysaccharide (LPS) and Gram-positive lipoteichoic acid (LTA) have been shown to interact specifically with LF, resulting in disruption of pathogen cell membranes, proteolysis of virulence factors and inhibition of their ability to adhere to the host cells through binding with glycosaminoglycans (GAGs: Taha et al., Reference Taha, El barbary, Ibrahim, Mohammed and Wahba2019).

The application of LF in the dairy industry may face some challenges, such as its purity, iron saturation level, heat processing of the milk, presence of various chelating substances, water activity, pH, dairy product constituents (lipid, protein, and carbohydrate) and cations (Mg2 + and Ca2 + : Rybarczyk et al., Reference Rybarczyk, Kieckens, Vanrompay and Cox2017). Some studies have reported that LF can promote the population growth of some lactic acid bacteria, although the mechanism of action has not yet been fully understood (Inay et al., Reference Inay, Da Silva, Honjoya, Sugimoto, De Souza, De Santana, De Rezende Costa and Aragon-Alegro2012). Hence, its effect on the starter culture is still not understood and requires further investigation. Therefore, this study aimed to investigate the antimicrobial effect of LF on the foodborne pathogens S. aureus, E. coli, STEC, S. typhimurium and B. cereus, in addition to P. aeruginosa, as one of the most common spoilage microorganisms in dairy products. Moreover, two in vitro experimental lab-manufactured set yoghurt were prepared, one to evaluate the LF effect on starter culture activity and sensory properties and the other a challenged model with Shiga toxin-producing E. coli to evaluate the LF effect on its survivability over a 14-day cold storage period.

Material and methods

Determination of the minimum inhibitory concentration (MIC) of LF: preparation of the bacterial strains

Antimicrobial activity was assessed using S. aureus ATCC25923, E. coli 25922, S. typhimurium14028, B. cereus 10876 and P. aeruginosa 27853 which were obtained from National Research Institute of Dokki, Egypt as well as a Shiga toxin-producing E. coli (STEC) of dairy origin previously isolated and identified by our research team (Fahim et al., Reference Fahim, Ghoneim, Morgan and Abdel Aal2016). A pure culture of each bacterial strain was grown overnight in nutrient broth (Oxoid, USA) containing 0.6% yeast extract (Hi-media, UK) at 37°C. A ten-fold serial dilution was prepared, then a viable colony count of each strain was applied on their specific media (S. aureus; Baird-Parker (Hi-media, UK), E. coli; eosin methylene blue (Hi-media, UK), S. typhimurium; MacConkey agar (Hi-media, UK), B. cereus; mannitol egg yolk polymyxin agar (Hi-media, UK), P. aeruginosa; Pseudomonas agar base (Hi-media, UK) following the method described by Ahmed et al. (Reference Ahmed, Ibrahim, Abdel-Salam and Fahim2021).

Preparation of LF concentrations

Different concentrations of LF (Sigma Aldrich, USA) were prepared using sterile distilled water (0.0001–0.001–0.01–0.1–1–2.5–5 mg/ml). The freshly prepared concentrations were used in the experiment.

Broth micro dilution method to determine the MIC of LF

MIC of the LF against the tested strains (S. aureus at 1.3 × 109 cfu/ml, E. coli at 2.6 × 109 cfu/ml, STEC at 2.79 × 1012 cfu/ml, S. typhimurium at 3.7 × 109 cfu/ml, B. cereus at 1.8 × 109 cfu/ml and P. aeruginosa at 85 × 107 cfu/ml) was performed using the broth micro dilution method modified by Habty and Ali (Reference Habty and Ali2022).

Impact of the different concentrations of LF on the activity of starter culture and sensory properties of laboratory manufactured set yoghurt

Raw buffalo milk was obtained from the dairy production unit, Faculty of Agriculture, Cairo University, Egypt. Raw milk was tested and confirmed to be free from any inhibitory substances following the method described by Ahmed et al. (Reference Ahmed, Ibrahim, Abdel-Salam and Fahim2021). Raw milk was laboratory pasteurized at 80°C for 10 min, then cooled immediately in an ice bath to the inoculation temperature (44.5 ± 0.5°C) according to Oktavia et al. (Reference Oktavia, Radiati and Rosyidi2016). The amount of starter culture (Yo-Flex, UK) was added to the milk following the manufacturer's instructions with thorough mixing. Following that, milk was divided into six equal portions for the five treatments, which were derived from MIC concentrations; 0.0001% LF (treatment 1), 0.001% LF (treatment 2), 0.01% LF (treatment 3), 0.1% LF (treatment 4), 2.5% LF (treatment 5) as well as a control group without LF (treatment 6). The treated milk samples were thoroughly mixed and placed into sterile cups (200 g capacity) and incubated in a water bath at 44.5 ± 0.5°C for 3–4 h (until complete coagulation of the yoghurt), then transferred to a refrigerator (4°C). Samples were examined at zero time (end of yoghurt manufacturing), after 24, 72 h and every 3 d until the end of the storage period (14 d/4°C) for titratable acidity% according to APHA (2004). Sensory evaluation was done according to Zakaria et al. (Reference Zakaria, Zakaria, Abdelhiee, Fadl and Ombarak2020) for treatments 1 and 2, these being the concentrations used in the viability study. A total of 21 panelists participated in the evaluation, 10 women and 11 men from the students and staff of the Faculty of Veterinary Medicine, Cairo University, ranging in age from 20 to 40 years. They received a training session for the yoghurt descriptive profile of sensory parameters: appearance (10), body and texture (30), flavor (45), packaging (5), and taste (10).

The activity of yoghurt starter culture was defined by its ability to ferment milk lactose and produce the acid that is responsible for the formation of yoghurt. Therefore, we depended on measuring the amount of lactic acid produced during the fermentation step rather than counting the starter culture.

Survivability of STEC in inoculated fortified lab-manufactured set yoghurt

Lab-pasteurized milk was inoculated with 4–6 log10 cfu/ml STEC followed by the addition of yoghurt starter culture according to the manufacturer's instructions. The inoculated milk was divided into three groups; the first was fortified with 0.0001% LF (treatment 1), the second with 0.001% LF (treatment 2), and the third was left as a control without the addition of LF. Both treatments and control groups were completed as described before. Samples were examined for total STEC count at zero-time (after complete manufacture of yoghurt), after 24, 72 h and every 3 d until the end of the storage period (14 d/4°C) following the method described by Silva et al. (Reference Silva, Taniwaki, Junqueira, Silveira, Okazaki and Gomes2018).

A detailed account of the full materials and methods is provided in the online Supplementary File.

Statistical analysis

All experiments were carried out in triplicate and the average results were calculated and recorded using SPSS Version 26.0 software. Comparisons of sensory evaluation, titratable acidity and the viability study between the fortified and control groups and between the different LF concentrations were done using one-way analysis of variance (ANOVA), Kruskal–Wallis H and Mann–Whitney U tests. Significant results were set at P-value < 0.05.

Results

Determination of MIC of LF

Antimicrobial activity of the different LF concentrations (from 0.0001 to 5 mg/ml) against foodborne pathogens and spoilage microorganisms was tested using the micro dilution method. Concentrations were chosen based on previous studies and to determine the minimum effective concentration that could be used at the industrial level without affecting the starter culture activity. The results shown in Table 1 revealed that LF could affect all tested strains, of which E. coli and STEC were the most sensitive microorganisms with MIC values of 0.0001 mg/ml. However, P. aeruginosa and B. cereus were quite resistant, with an MIC of 2.5 mg/ml whilst S. typhimurium and S. aureus showed moderate susceptibility with MIC values of 0.01 and 0.1 mg/ml (Table 1).

Table 1. MIC values of LF against the examined microorganisms

Impact of different concentrations of LF on the activity of yoghurt starter culture

The onset of milk coagulation and the time required for making fortified yoghurt in both treated and control samples were observed and the titratable acidity percentage (TA%) was assessed throughout the processing and storage period (Fig. 1). Results revealed that there was no statistical significant difference between the control and fortified groups (P > 0.05). At the end of the storage period, acidity % of yoghurt samples reached 0.99, 1, 1.18, 1.2 and 1.22% in treatments T1 to T5, respectively. The value of this parameter increased over storage time, and the increase was non-significantly associated with increased LF concentrations.

Figure 1. Titratable acidity % of lab-manufactured fortified set yoghurt with different concentrations of the lactoferrin (LF) over the storage period of 14 d at 4°C.

Control, (without Lf); T1, (0.0001 mg/ml); T2, (0.001 mg/ml); T3, (0.01 mg/ml); T4, (0.1 mg/ml); T5, (2.5 mg/ml).

Influence of LF on the sensory properties of lab-manufactured set yoghurt

The lab-manufactured set yoghurt fortified with two concentrations of LF (0.0001 and 0.001 mg/ml) and the control group (without fortification) were sensory evaluated and as seen in Table 2 both showed a statistically significant difference (improvement) in comparison to the control group (P < 0.05) with no difference between them. The fortified samples scored grade A concerning the overall acceptability throughout the storage period of 14 d/4°C, whilst the control samples had grade A during the first day only and then dropped to grade B until the end of the storage period. Briefly, flavor and body and texture scores of LF-fortified yoghurt achieved excellent scores throughout the storage period, while the control group achieved excellent scores during the first day then the score decreased to very good till the end of the storage period (Table 2).

Table 2. Sensory evaluation of the fortified laboratory manufactured set yoghurt with the studied concentrations of LF

C, control (without lactoferrin); T1, Treatment 1(0.0001 mg/ml LF); T2, Treatment 2 (0.001 mg/ml LF); acceptability grading as follows, Grade A (excellent), >86%; Grade B (very good), 73≤ 86%; Grade C (good), 60 ≤ 73%.

Survivability of STEC in inoculated fortified lab-manufactured set yoghurt

The data are shown in Fig. 2. After 72 h of storage STEC survivability was reduced by 70, 91.6 and 56% in T1 (0.0001 mg/ml LF), T2 (0.001 mg/ml LF) and control (without LF) samples, respectively. In T1 and T2 this decline continued until the inoculated strain completely disappeared by the end of the storage period, while STEC remained viable (at 103 cfu/g) in the control group until the end of the storage period (Fig. 2).

Figure 2. Counts of Shiga toxin producing E. coli (log10/g) during the storage period of inoculated fortified lab-manufactured set yoghurt (14 d/ 4°C).

Control, (without Lf); T1, (0.0001 mg/ml); T2, (0.001 mg/ml).

Discussion

Foodborne illness causes economic losses and puts the general public's health at risk (Jenkins et al., Reference Jenkins, Bird, Wensley, Wilkinson, Aird, MacKintosh, Greig, Simpson, Byrne, Wilkinson, Godbole, Arunachalam and Hughes2022). Consumer awareness of the hazards linked to the use of synthetic chemical preservatives has grown significantly in recent years. Furthermore, food producers confront significant hurdles in producing food that is both safe and of high quality in terms of nutritional benefits and sensory attributes (Ahmed et al., Reference Ahmed, Ibrahim, Abdel-Salam and Fahim2021). LF has significant antibacterial activity as its iron binding capability is double that of transferrin, and this bond is strong enough to withstand the low pH values of fermented dairy products (Duran, Reference Duran2021). Therefore, it is considered a great natural alternative to chemical preservatives, especially after the FDA certification as a food additive (Franco et al., Reference Franco, Pérez, Conesa, Calvo and Sánchez2018).

Our results confirmed the antibacterial activity of LF and showed that gram-negative pathogens were more susceptible than Gram-positive ones. This result could be attributed to the interaction of LF with the anionic structure of LPS in the bacterial membrane, causing membrane instability, detachment of LPS and bacterial death (Hafez et al., Reference Hafez, El Ismael, Mahmoud and Elaraby2013; Sijbrandij et al., Reference Sijbrandij, Ligtenberg, Nazmi, Veerman, Bolscher JG and Bikker2017). Likewise, Kutila et al. (Reference Kutila, Pyörälä, Saloniemi and Kaartinen2003) revealed that the most effective inhibitory activity of LF was against Gram-negative bacteria (E. coli and P. aeruginosa) rather than Gram-positive (S. aureus and coagulase-negative S. aureus). However, Jahani et al. (Reference Jahani, Shakiba and Jahani2015) observed the opposite, that bactericidal effects were more pronounced against Gram-positive bacteria (S. epidermidis, B. cereus) than Gram-negative bacteria (C. jejuni, and Salmonella). Moreover, Karam-Allah et al. (Reference Karam-Allah, Abo-Zaid, Refae, Shaaban, Saad, Hassanin and El-Waseif2022) recorded that LF was more effective against Gram-positive (S. aureus and B. cereus) than Gram-negative (E. coli). In the present study, E. coli and STEC were the most susceptible to LF, s effect, which may be attributed to the positively charged N-terminus of LF which hinders the interaction between LPS and bacterial cations (Ca2 +  and Mg2 + ) and interferes with aggregative proliferation in E. coli (Moradian et al., Reference Moradian, Sharbafi and Rafiei2014). On the other hand, B. cereus and P. aeruginosa were the most resistant to the effects of LF, which may be ascribed to their capacity to produce biofilm that protects them from the LF effect. Biofilm-associated bacteria are up to 1000 times more resistant to antimicrobial agents than planktonic bacteria (Majed et al., Reference Majed, Faille, Kallassy and Gohar2016; Thi et al., Reference Thi, Wibowo and Rehm2020). Our results were nearly similar to those obtained by Hafez et al. (Reference Hafez, El Ismael, Mahmoud and Elaraby2013) who reported that 3 mg/ml of the LF completely inhibited E. coli after 1 h of incubation, while the time required for P. aeruginosa suppression extended to 6 h and there was a slight inhibition of S. aureus compared to control. On the contrary, Embleton et al. (Reference Embleton, Berrington, McGuire, Stewart and Cummings2013) reported that P. aeruginosa was more susceptible to LF effect than E. coli.

We examined the effect of LF on starter culture activity. The results (Fig. 1) revealed that the addition of LF to yoghurt had no effect on the yoghurt's onset of coagulation time or the starter culture's rate of growth throughout the processing stage, therefore it can be added safely in the fermented products. Numerous studies showed that the microbial growth-stimulating effect of LF may be linked to the presence of proteins that bind LF on the bacterial surface. Therefore, LF may be a pathway for acquiring iron if the bacteria (in this case, starter culture) have exterior membrane receptors capable of specifically attaching to the LF-iron complex, causing the internalization of the metal (Modun et al., Reference Modun, Morrissey and Williams2000; Kim et al., Reference Kim, Ohashi, Tanaka, Kumura, Kim, Kwon, Goh and Shimazaki2004). Our data are in agreement with reports of Matijašić et al. (Reference Matijašić, Oberčkal, Lorbeg, Paveljšek, Skale, Kolenc, Gruden, Ulrih, Kete and Justin2020) and Duran (Reference Duran2021), who investigated the impact of various LF concentrations on the growth rate of lactic acid bacteria in raw milk and found that 5.0 mg/ml promoted the growth of lactic acid bacteria. On the other hand, Zakaria et al. (Reference Zakaria, Zakaria, Abdelhiee, Fadl and Ombarak2020) reported that the titratable acidity% increase while processing yoghurt fortified with LF was slower than that of the control, which they attributed to the partial inhibition of lactic acid-producing microorganisms. Additionally, Franco et al. (Reference Franco, Castillo, Pérez, Calvo and Sánchez2010) studied the effect of different concentrations of LF at 2 levels of iron saturation (holo –apo) on the fermentation process of milk and found LF-holo did not affect the fermentation of milk and its transformation into yoghurt, while the addition of LF-apo delayed milk acidification. Type, iron saturation level, and concentrations of LF are variables influencing LAB to varying degrees.

We examined the effect of LF on the sensory properties of fortified set yogurt (Table 2). LF is a component of milk, so it is expected that its presence in fortified dairy products would not have a negative impact on their organoleptic and sensory qualities, however, this has not previously been fully investigated. Results revealed a positive effect of LF on the sensory properties of fortified yoghurt. Similarly, Ombarak et al. (Reference Ombarak, Saad and Elbagory2019) demonstrated that adding LF could enhance the sensory qualities of cheese, with larger concentrations of LF producing the best results during the storage period. Furthermore, Zakaria et al. (Reference Zakaria, Zakaria, Abdelhiee, Fadl and Ombarak2020) reported that LF-treated yoghurt was satisfactory and had no adverse effects on the yoghurt's taste or odor. These findings open the door for more applications of lactoferrin in other dairy products as they showed that adding LF to fermented dairy products would not only have antibacterial activity but could also improve their sensory attributes without disrupting the fermentation process.

STEC is one of the most prevalent pathogens affecting humans globally and causing serious infections such as hemorrhagic colitis, stomach pain, bloody diarrhea and hemolytic uremic syndrome. Moreover, it is an important cause of acute renal failure in children (Kieckens et al., Reference Kieckens, Rybarczyk, Barth, Menge, Cox and Vanrompay2017). STEC could be isolated from several foods, including yoghurt which has an acidic pH (4.4: Fahim et al., Reference Fahim, Ghoneim, Morgan and Abdel Aal2016). E. coli O157:H7 was found to survive for 10 d in inoculated yoghurt during a study conducted by Cutrim et al. (Reference Cutrim, Barros, Franco and Cortez2017). Being highly acid resistant, the infectious dose of E. coli O157:H7 is very low, between 1 and 100 cfu/g, much lower than for most other entero-pathogens, which increases the risk of disease (Ababu et al., Reference Ababu, Endashaw and Fesseha2020). Contamination of dairy products with such pathogenic organisms could be attributed to the poor hygienic conditions under which they were processed and/or stored. Its presence is an indicator of fecal contamination and suggests that other food-borne pathogens of fecal origin may also be present (Mohamed et al., Reference Mohamed, Abdel, Awad, All and Ahmed2020). We examined the survivability of STEC in inoculated LF fortified yogurt. A viability study with two concentrations of LF (0.0001 and 0.001 mg/ml) demonstrated the presence of a statistically significant difference between the test and control groups as well as between the two LF concentrations, the higher being more effective (P < 0.05). Xu et al. (Reference Xu, Zhao, Zou and Yang2017) and Ombarak et al. (Reference Ombarak, Saad and Elbagory2019) used higher concentrations of LF (0.5 and 4 mg/ml, respectively) to achieve the same effect against E. coli O157:H7, as did Hassan et al. (Reference Hassan, Bebawy, Hafez and Hasan W2022) in Tallega cheese (1 mg/ml LF in this case). On the other hand, Taha et al. (Reference Taha, El barbary, Ibrahim, Mohammed and Wahba2019) reported that survivability of E. coli O26 was not affected by either 10 or 20 mg/ml LF, which they attributed to bacterial defense mechanisms developed by E. coli that prevented LF from binding with it. Positive effects of LF against inoculated E. coli could be attributed to its binding to ions which are crucial for microbial survival and growth, leading to inhibition of microbial proliferation and death. Since LF has significant levels of amylase, DNase, RNase and ATPase activity, it can kill bacteria by damaging their nucleic acids (Taha et al., Reference Taha, El barbary, Ibrahim, Mohammed and Wahba2019).

In conclusion, this study emphasized the further potential applications of LF as a natural preservative alternative in fermented and non-fermented dairy products in the dairy industry.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0022029923000675

References

Ababu, A, Endashaw, D and Fesseha, H (2020) Isolation and antimicrobial susceptibility profile of Escherichia coli O157: H7 from raw milk of dairy cattle in Holeta District, central Ethiopia. International Journal of Microbiology 2020, 18.CrossRefGoogle Scholar
Abdel-Salam, AB and Soliman, NSM (2019) Prevalence of some deteriorating microorganisms in some varieties of cheese. Open Journal of Applied Sciences 9, 620630.10.4236/ojapps.2019.97050CrossRefGoogle Scholar
Adam, AH, Aly, SA and Saad, MF (2021) Evaluation of microbial quality and safety of selected dairy products with special focus on toxigenic genes of Bacillus cereus. Mljekarstvo 71, 257268.Google Scholar
Ahmed, LI, Ibrahim, N, Abdel-Salam, AB and Fahim, KM (2021) Potential application of ginger, clove and thyme essential oils to improve soft cheese microbial safety and sensory characteristics. Food Bioscience 42, 101177.CrossRefGoogle Scholar
American Public Health Association “APHA” (2004) Standard Methods of Examination of Dairy Products, 17th Edn. Washington, DC, USA: American Public Health Association.Google Scholar
Atia, RM, Mohamed, HA, Abo ElRoos, NA and Awad, DAB (2020) Incidence of Pseudomonas species and effect of their virulence factors on milk and milk products. Benha Veterinary Medical Journal 39, 9599.Google Scholar
Cutrim, CS, Barros, R, Franco, RM and Cortez, MAS (2017) Escherichia coli O157:H7 survival in traditional and low lactose yoghurt during fermentation and cooling periods. Ciência Animal Brasileira 18, 19.CrossRefGoogle Scholar
Duran, A (2021) The effect of bovine lactoferrin on the microbiological properties of raw milk. Gida/The Journal of Food 46, 681691.CrossRefGoogle Scholar
Eleboudy, A, Amer, A, Nasief, M and Eltony, S (2015) Occurrence and behavior of pseudomonas organisms in white soft cheese. Alexandria Journal Vetrinary Science 44, 74.10.5455/ajvs.166387CrossRefGoogle Scholar
Embleton, ND, Berrington, JE, McGuire, W, Stewart, CJ and Cummings, SP (2013) Lactoferrin: antimicrobial activity and therapeutic potential. Seminars in Fetal and Neonatal Medicine 18, 143149.CrossRefGoogle ScholarPubMed
Fahim, KM, Ghoneim, RSH, Morgan, SD and Abdel Aal, AA (2016) Prevalence of Shiga toxin producing Escherichia coli (STEC) in milk and some dairy products. Journal of Egyptian Veterinary Medicine Association 76, 209225.Google Scholar
Franco, I, Castillo, E, Pérez, MD, Calvo, M and Sánchez, L (2010) Effect of bovine lactoferrin addition to milk in yoghurt manufacturing. Journal of Dairy Science 93, 44804489.CrossRefGoogle Scholar
Franco, I, Pérez, MD, Conesa, C, Calvo, M and Sánchez, L (2018) Effect of technological treatments on bovine lactoferrin: an overview. Food Research International 106, 173182.CrossRefGoogle ScholarPubMed
Gonelimali, FD, Lin, J, Miao, W, Xuan, J, Charles, F, Chen, M and Hatab, SR (2018) Antimicrobial properties and mechanism of action of some plant extracts against food pathogens and spoilage microorganisms. Frontiers in Microbiology 9, 19.CrossRefGoogle ScholarPubMed
Habty, S and Ali, DN (2022) Efficiency of lactoferrin to eradicate multidrug resistant Staphylococcus aureus isolated from some dairy products. Research Square. https://doi.org/10.21203/rs.3.rs-1354085/v1Google Scholar
Hafez, SMA, El Ismael, AB, Mahmoud, MB and Elaraby, AKA (2013) Development of new strategy for non-antibiotic therapy: bovine lactoferrin has a potent antimicrobial and immunomodulator effects. Advances in Infectious Diseases 3, 185192.CrossRefGoogle Scholar
Halim, EYA, El-Essawy, H, Awad, AAN, El-Kutry, MS and Ahmed, LI (2022) Estimating the microbial safety and sensory characteristics of some imported dairy products retailed in the Egyptian markets. Advances in Animal and Veterinary Sciences 10, 488499.Google Scholar
Hassan, AM, Bebawy, JHT, Hafez, MR and Hasan W, S (2022) Using lactoferrin as a trial to control E. coli and S. aureus isolated from some types of cheese. Assiout Veterinary Medical Journal 68, 4956.Google Scholar
Inay, OM, Da Silva, AS, Honjoya, E, Sugimoto, HH, De Souza, CHB, De Santana, EHW, De Rezende Costa, M and Aragon-Alegro, LC (2012) Action of lactoferrin on the multiplication of Lactobacillus casei in vitro and in Minas fresh cheese. Semina:Ciencias Agrarias 33, 31533162.Google Scholar
Jahani, S, Shakiba, A and Jahani, L (2015) The antimicrobial effect of lactoferrin on Gram-negative and Gram-positive bacteria. International Journal of Infection, 2, e27954. https://doi.org/10.17795/iji27594Google Scholar
Jenkins, C, Bird, PK, Wensley, A, Wilkinson, J, Aird, H, MacKintosh, A, Greig, DR, Simpson, A, Byrne, L, Wilkinson, R, Godbole, G, Arunachalam, N and Hughes, GJ (2022) Outbreak of STEC O157:H7 linked to a milk pasteurization failure at a dairy farm in England. Epidemiology and Infection 150, 17.CrossRefGoogle Scholar
Karam-Allah, AA, Abo-Zaid, EM, Refae, MM, Shaaban, HA, Saad, SA, Hassanin, AM and El-Waseif, MA (2022) Functional stirred yoghurt fortified with buffalo, bovine, mix colostrum and lactoferrin, effect of lactoferrin on pathogenic bacteria and amino acids of buffalo, bovine colostrum and lactoferrin. Egyptian Journal of Chemistry 65, 583594.Google Scholar
Kell, DB, Heyden, EL and Pretorius, E (2020) The biology of lactoferrin, an iron-binding protein that can help defend against viruses and bacteria. Frontiers in Immunology 11, 115.CrossRefGoogle ScholarPubMed
Kieckens, E, Rybarczyk, J, Barth, SA, Menge, C, Cox, E and Vanrompay, D (2017) Effect of lactoferrin on release and bioactivity of Shiga toxins from different Escherichia coli O157:H7 strains. Veterinary Microbiology 20, 2937.CrossRefGoogle Scholar
Kim, WS, Ohashi, M, Tanaka, T, Kumura, H, Kim, GY, Kwon, IK, Goh, JS and Shimazaki, KI (2004) Growth-promoting effects of lactoferrin on L. acidophilus and Bifidobacterium spp. Bio Metals 17, 279283.Google Scholar
Kutila, T, Pyörälä, S, Saloniemi, H and Kaartinen, L (2003) Antibacterial effect of bovine lactoferrin against udder pathogens. Acta Veterinaria Scandinavica 44, 3542.CrossRefGoogle ScholarPubMed
Majed, R, Faille, C, Kallassy, M and Gohar, M (2016) Bacillus cereus biofilms-same, only different. Frontier Microbiology 7, 1054.Google ScholarPubMed
Matijašić, BB, Oberčkal, J, Lorbeg, PM, Paveljšek, D, Skale, N, Kolenc, B, Gruden, Š, Ulrih, NP, Kete, M and Justin, MZ (2020) Characterisation of lactoferrin isolated from acid whey using pilot-scale monolithic ion-exchange chromatography. Processes, 8, 804.Google Scholar
Modun, B, Morrissey, J and Williams, P (2000) The staphylococcal transferrin receptor: a glycolytic enzyme with novel functions. Trends in Microbiology 8, 231237.CrossRefGoogle ScholarPubMed
Mohamed, SY, Abdel, A, Awad, N, All, A and Ahmed, LI (2020) Microbiological quality of some dairy products with special reference to the incidence of some biological hazards. International Journal of Dairy Science 15, 2837.CrossRefGoogle Scholar
Moradian, F, Sharbafi, R and Rafiei, A (2014) Lactoferrin, isolation,purification and antimicrobial effects. Journal of Medical and Bioengineering 3, 203206.CrossRefGoogle Scholar
Nadi, WG, Ahmed, LI, Awad, AAN and Taher, EM (2023) Occurrence, antimicrobial resistance, and virulence of Staphylococcus aureus, Escherichia coli, and Pseudomonas aeruginosa isolated from dairy products. International Journal of Veterinary Science. ‘in press’. https://doi.org/10.47278/journal.ijvs/2023.079Google Scholar
Niaz, B, Saeed, F, Ahmed, A, Imran, M, Maan, AA, Khan, MKI, Tufail, T, Anjum, FM, Hussain, S and Suleria, HAR (2019) Lactoferrin (LF): a natural antimicrobial protein. International Journal of Food Properties 22, 16261641.CrossRefGoogle Scholar
Oktavia, H, Radiati, LE and Rosyidi, D (2016) Evaluation of physicochemical properties and exopolysaccharides production of single culture and mixed culture in set yoghurt. Indonesian Journal of Environment and Sustainable Development 7, 5259.Google Scholar
Ombarak, R, Saad, M and Elbagory, A (2019) Biopreservative effect of lactoferrin against foodborne pathogens inoculated in Egyptian soft cheese “Karish cheese”. Alexandria Journal of Veterinary Sciences 63, 97103.CrossRefGoogle Scholar
Quinto, EJ, Caro, I, Villalobos-Delgado, LH, Mateo, J, De-Mateo-silleras, B and Redondo-Del-río M, P (2019) Food safety through natural antimicrobials. Antibiotics 8, 130.CrossRefGoogle ScholarPubMed
Rybarczyk, J, Kieckens, E, Vanrompay, D and Cox, E (2017) In vitro and in vivo studies on the antimicrobial effect of lactoferrin against Escherichia coli O157:H7. Veterinary Microbiology 202, 2328.CrossRefGoogle ScholarPubMed
Salih, NKM, Abdullahi, N and Al Taweel, H (2018) Latent period of Pseudomonas aeruginosa in dairy product (yogurt and pasteurized milk). Journal of Environmental Science Toxicology and Food Technology 12, 8894.Google Scholar
Sijbrandij, T, Ligtenberg, AJ, Nazmi, K, Veerman, ECI, Bolscher JG, M and Bikker, FJ (2017) Effects of lactoferrin derived peptides on simulants of biological warfare agents. World Journal of Microbiology and Biotechnology 33, 19.10.1007/s11274-016-2171-8CrossRefGoogle ScholarPubMed
Silva, ND, Taniwaki, MH, Junqueira, VCA, Silveira, NFA, Okazaki, MM and Gomes, RAR (2018) Microbiological Examination Methods of Food and Water: A Laboratory Manual, 2nd Edn. London, UK: CRC Press, Taylor& Francis Group.CrossRefGoogle Scholar
Taha, N, El barbary, H, Ibrahim, E, Mohammed, H and Wahba, N (2019) Application of lactoferrin as a trial to control E. coli O1and O26 in pasteurized milk. Benha Veterinary Medical Journal 36, 360366.CrossRefGoogle Scholar
Taher, EM, Hemmatzadeh, F, Aly, SA, Elesswy, HA and Petrovski, KR (2020) Molecular characterization of antimicrobial resistance genes on farms and in commercial milk with emphasis on the effect of currently practiced heat treatments on viable but non culturable formation. Journal of Dairy Science 103, 99369945.CrossRefGoogle Scholar
Taher, EM, Valtman, T and Petrovski, KR (2022) Presence of bacillus species in pasteurized milk and their phenotypic and genotypic antimicrobial resistance profile. International Journal of Dairy Technology 76, 6373.CrossRefGoogle Scholar
Thi, MTT, Wibowo, D and Rehm, BHA (2020) Pseudomonas aeruginosa biofilms. International Journal of Molecular Sciences 21, 8671.CrossRefGoogle ScholarPubMed
Wang, B, Timilsena, YP, Blanch, E and Adhikari, B (2019) Lactoferrin: structure, function, denaturation and digestion. Critical Reviews in Food Science and Nutrition 59, 580596.CrossRefGoogle ScholarPubMed
Xu, R, Zhao, X-Y, Zou, J and Yang, Y (2017) Effect of lactoferrin and its hydrolysates prepared with pepsin and trypsin on Escherichia coli O157:H7. Advance Journal of Food Science and Technology 13, 279284.CrossRefGoogle Scholar
Zakaria, AM, Zakaria, HM, Abdelhiee, EY, Fadl, SE and Ombarak, RA (2020) The impact of lactoferrin fortification on the health benefits and sensory properties of yogurt. Journal of Current Veterinary Research 2, 105112.CrossRefGoogle Scholar
Figure 0

Table 1. MIC values of LF against the examined microorganisms

Figure 1

Figure 1. Titratable acidity % of lab-manufactured fortified set yoghurt with different concentrations of the lactoferrin (LF) over the storage period of 14 d at 4°C.Control, (without Lf); T1, (0.0001 mg/ml); T2, (0.001 mg/ml); T3, (0.01 mg/ml); T4, (0.1 mg/ml); T5, (2.5 mg/ml).

Figure 2

Table 2. Sensory evaluation of the fortified laboratory manufactured set yoghurt with the studied concentrations of LF

Figure 3

Figure 2. Counts of Shiga toxin producing E. coli (log10/g) during the storage period of inoculated fortified lab-manufactured set yoghurt (14 d/ 4°C).Control, (without Lf); T1, (0.0001 mg/ml); T2, (0.001 mg/ml).

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