key: cord-0743949-yaw84gf9
authors: Montone, Angela Michela Immacolata; Papaianni, Marina; Malvano, Francesca; Capuano, Federico; Capparelli, Rosanna; Albanese, Donatella
title: Lactoferrin, Quercetin, and Hydroxyapatite Act Synergistically against Pseudomonas fluorescens
date: 2021-08-26
journal: Int J Mol Sci
DOI: 10.3390/ijms22179247
sha: d1b6b3209e203e3841fb26778db91fe87f2c82ff
doc_id: 743949
cord_uid: yaw84gf9

Pseudomonas fluorescens is an opportunistic, psychotropic pathogen that can live in different environments, such as plant, soil, or water surfaces, and it is associated with food spoilage. Bioactive compounds can be used as antimicrobials and can be added into packaging systems. Quercetin and lactoferrin are the best candidates for the development of a complex of the two molecules absorbed on bio combability structure as hydroxyapatite. The minimum inhibiting concentration (MIC) of single components and of the complex dropped down the single MIC value against Pseudomonas fluorescens. Characterization analysis of the complex was performed by means SEM and zeta-potential analysis. Then, the synergistic activity (C(syn)) of single components and the complex was calculated. Finally, the synergistic activity was confirmed, testing in vitro its anti-inflammatory activity on U937 macrophage-like human cell line. In conclusion, the peculiarity of our study consists of optimizing the specific propriety of each component: the affinity of lactoferrin for LPS; that of quercetin for the bacterial membrane. These proprieties make the complex a good candidate in food industry as antimicrobial compounds, and as functional food.

Pseudomonas fluorescens is a Gram-negative, aerophile, and psychotropic bacterium. The psychotropic property of this bacterium favors its growth-even in cold roomsand reduces the shelf life of food products. Thus, Pseudomonas fluorescens contributes particularly to the deterioration of fish, milk, and meat stored at low temperatures.

Pseudomonas spp.-including Pseudomonas fluorescens-account for up to 97% of bacteria isolated in cattle meat stored in cold rooms [1] [2] [3] [4] . These species secrete several enzymes (protease, lipase, and thermostable lecithinase) that cause deterioration of food products [5, 6] , a source of heavy economic losses to the food industry [7] . So far, numerous antimicrobial additives have been exploited in order to control microbial contamination during the food supply chain [8] [9] [10] . Generally, consumers consider food additives as very unhealthy. Since consumers see chemical additives as dangerous, the food industry has decided to use natural molecules to control bacterial contamination [11] [12] [13] . Natural molecules often are active only at high concentrations and against a limited number of bacterial species. This limit can partially be reduced using lower concentration of several components. The food industry generally prefers adding additives to the packaging, rather than directly to the product [14] . However, this solution needs using a carrier to control the additive release and a scaffold to preserve the activity of the additives throughout the shelf life of the product.

Among the potential components to use against Pseudomonas fluorescens, we exploited quercetin, lactoferrin, and hydroxyapatite. Quercetin (que) is a polyphenolic molecule common in plants and known as an efficient antioxidant. In plants, quercetin is present in the forms of quercetin-3-O-rutinoside (rutin), quercetin-3-O-glycoside, and quercetin-3-O-(6 -O-acetil)-glycoside. Quercetin exerts its antioxidant activity principally by eliminating free radicals [15] , chelating metallic ions [16] , and inhibiting lipid peroxidation [17] ; in addition, it is active against bacteria and yeast (Pseudomonas aeruginosa, Salmonella enteritidis, Staphylococcus aureus, Escherichia coli, Proteus spp., and Aspergillus flavus) [18] .

Quercetin exerts its antibacterial activity by degrading the bacterial cell wall, altering cell permeability, protein synthesis, enzymatic activity, and inhibition of nucleic acid synthesis [18] [19] [20] [21] [22] .

Lactoferrin (lacto) is a glycoprotein with a molecular weight of 78 Kd. Its peculiar property is of binding iron-abundant in animal and human milk-and in exocrine secretions. Originally, the antimicrobial activity of lactoferrin was attributed to iron chelation; at present, we know that it directly damages the external membrane of Gram-negative bacteria binding to the lipid A of LPS (Lipopolysaccharide) and promotes its removal from the bacterial surface [23] . Further, lactoferrin and quercetin are both anti-inflammatory molecules [24] . In particular, quercetin controls the activation of NF-kB (nuclear factor kappa-light-chain-enhancer of activated B cells) [25] and the release of pro-inflammatory cytokine (TNF-α, IL-1β, IL-6, IL-8) [26] . Lactoferrin modulates the expression of proinflammatory cytokine [27, 28] , chemiotactic factor production, and the expression of adhesion molecules [29] . This property as suggested their use against COVID-19 [30] .

Hydroxyapatite (HA) [Ca 5 (PO 4 ) 3 (OH)]-an inorganic mineral and basic component of the bones-has also been shown efficient as a carrier-molecule for its property of interacting with antimicrobial peptides, and organisms such as bacteriophages [31, 32] . Moreover, it has already been successfully tested as a stabilizer of quercetin [33] and lactoferrin [34] against Pseudomonas spp. and Salmonella spp., respectively.

The purpose of the present study was to test the potential utility of a complex that included quercetin and lactoferrin as antimicrobials, and hydroxyapatite as a carrier for the food industry.

First, we tested in vitro the antimicrobial activity of quercetin and lactoferrin against Pseudomonas fluorescens, individually and in combination as a complex with hydroxyapatite. We established the minimum inhibiting concentration (MIC) of single components and of the complex. Then, we calculated the synergistic activity (C syn ) of single components and of the complex. Finally, we confirmed the synergistic activity of the complex, testing in vitro its anti-inflammatory activity on U937 macrophage-like human cell line.

First, we tested separately Que and Lacto against Pseudomonas fluorescens. Que displayed a slightly higher antimicrobial activity ( Figure 1a ). Next, we tested Que and lacto, each in combination with HA. Que and Lacto displayed the same MIC values (500 ppm) (Figure 1b) , which is much higher, compared to the concentration of 250 ppm reported as the maximum concentration approved [29, 35] , suggesting that HA does not show a significant improvement of Que and Lacto antimicrobial activity. In order to determine their optimal concentrations, Que and Lacto were tested together against Pseudomonas fluorescens. The MIC of the two molecules together was 200 ppm (w/v) ( Figure 2 ). This MIC value (200 ppm) was combined with HA and tested at different concentrations and different combinations. Specifically, interaction of Que and Lacto with HA displayed different antibacterial activity, depending upon which molecule was added first to HA. The highest inhibition was obtained when the HA was first incubated with Lacto and then with Que (smaller compared to lacto) at a concentration of 100 ppm (w/v) ( Figure 3b ). Instead, when the order was inverted (HA-Que-Lacto) at the same concentration (100 ppm), the inhibition was only 40% (Figure 3a ).

. Figure 2 . Antimicrobial activity of Que and Lacto together against Pseudomonas fluorescens (10 6 CFU/mL). Statistical analysis was performed and considered statistically significant when p < 0.05 (** p < 0.01, **** p < 0.0001) according to two-way ANOVA multiple comparisons. In order to determine their optimal concentrations, Que and Lacto were tested together against Pseudomonas fluorescens. The MIC of the two molecules together was 200 ppm (w/v) ( Figure 2 ). This MIC value (200 ppm) was combined with HA and tested at different concentrations and different combinations. Specifically, interaction of Que and Lacto with HA displayed different antibacterial activity, depending upon which molecule was added first to HA. The highest inhibition was obtained when the HA was first incubated with Lacto and then with Que (smaller compared to lacto) at a concentration of 100 ppm (w/v) ( Figure 3b ). Instead, when the order was inverted (HA-Que-Lacto) at the same concentration (100 ppm), the inhibition was only 40% (Figure 3a ). In order to determine their optimal concentrations, Que and Lacto were tested together against Pseudomonas fluorescens. The MIC of the two molecules together was 200 ppm (w/v) ( Figure 2 ). This MIC value (200 ppm) was combined with HA and tested at different concentrations and different combinations. Specifically, interaction of Que and Lacto with HA displayed different antibacterial activity, depending upon which molecule was added first to HA. The highest inhibition was obtained when the HA was first incubated with Lacto and then with Que (smaller compared to lacto) at a concentration of 100 ppm (w/v) ( Figure 3b ). Instead, when the order was inverted (HA-Que-Lacto) at the same concentration (100 ppm), the inhibition was only 40% (Figure 3a ).

. Figure 2 . Antimicrobial activity of Que and Lacto together against Pseudomonas fluorescens (10 6 CFU/mL). Statistical analysis was performed and considered statistically significant when p < 0.05 (** p < 0.01, **** p < 0.0001) according to two-way ANOVA multiple comparisons. 

Results of the absorption showed that Que was fully absorbed on HA structure (1:100 w/v) for all quantities of Que tested (50-200 ppm) ( Figure 4a ). Additionally, for Lacto the absorption on HA is total, even between 50 and 100 ppm the absorbance results in negative values (Figure 4b ). The orange points in both graphs correspond to supernatant's absorption after reaction with HA. 

The complex HA-Lacto-Que, at the concentration of 100 ppm (w/v)-alone-can inhibit Pseudomonas fluorescens ( Figure 3b ). Next, we looked for a synergistic activity of the complex. The results shown in Table 1 clearly demonstrate that the highest activity 

Results of the absorption showed that Que was fully absorbed on HA structure (1:100 w/v) for all quantities of Que tested (50-200 ppm) ( Figure 4a ). Additionally, for Lacto the absorption on HA is total, even between 50 and 100 ppm the absorbance results in negative values (Figure 4b ). The orange points in both graphs correspond to supernatant's absorption after reaction with HA. 

Results of the absorption showed that Que was fully absorbed on HA structure (1:100 w/v) for all quantities of Que tested (50-200 ppm) (Figure 4a ). Additionally, for Lacto the absorption on HA is total, even between 50 and 100 ppm the absorbance results in negative values (Figure 4b ). The orange points in both graphs correspond to supernatant's absorption after reaction with HA. 

The complex HA-Lacto-Que, at the concentration of 100 ppm (w/v)-alone-can inhibit Pseudomonas fluorescens ( Figure 3b ). Next, we looked for a synergistic activity of the complex. The results shown in Table 1 clearly demonstrate that the highest activity 

The complex HA-Lacto-Que, at the concentration of 100 ppm (w/v)-alone-can inhibit Pseudomonas fluorescens ( Figure 3b ). Next, we looked for a synergistic activity of the complex. The results shown in Table 1 clearly demonstrate that the highest activity occurs when the complex HA-Lacto is used with Que at 100 ppm (C syn = 6.75 ± 2.67). However, the synergistic effect is also observed when the Que was used at 200 or 50 ppm (suboptimal concentrations). The fractional inhibitory concentration index (FIC index) was calculated to confirm the synergistic effect as reported by Bidaud et al. [36] . The complex HA-Lacto-Que, at the concentration of 100 ppm (w/v) has a synergistic effect with a value of 0.4 according to the interpretation that a FIC index of ≤0.5 suggests the synergistic interaction. 

To examine the interaction of HA with Lacto and Que at molecular level, we used the scanning electron microscope (SEM). HA show porous spherical aggregates of elongated crystallites. The average dimension of the particles was above the expected size of nanometer. This finding may result from the self-aggregation of the HA from a few hundred nanometers to a few microns (Figure 5a ) this hypothesis is in line with the absence of net charge of zeta potential [37] . The functionalization of HA with Lacto alone (Figure 5b ) and with Lacto-Que (Figure 5c ) reduced the porosity of HA as effect of adsorption of the two compounds inside the crystalline structure. occurs when the complex HA-Lacto is used with Que at 100 ppm (Csyn= 6.75 ± 2.67). However, the synergistic effect is also observed when the Que was used at 200 or 50 ppm (suboptimal concentrations). The fractional inhibitory concentration index (FIC index) was calculated to confirm the synergistic effect as reported by Bidaud et al. [36] . The complex HA-Lacto-Que, at the concentration of 100 ppm (w/v) has a synergistic effect with a value of 0.4 according to the interpretation that a FIC index of ≤0.5 suggests the synergistic interaction. 

To examine the interaction of HA with Lacto and Que at molecular level, we used the scanning electron microscope (SEM). HA show porous spherical aggregates of elongated crystallites. The average dimension of the particles was above the expected size of nanometer. This finding may result from the self-aggregation of the HA from a few hundred nanometers to a few microns (Figure 5a ) this hypothesis is in line with the absence of net charge of zeta potential [37] . The functionalization of HA with Lacto alone (Figure 5b ) and with Lacto-Que (Figure 5c ) reduced the porosity of HA as effect of adsorption of the two compounds inside the crystalline structure. This result is confirmed by independent z-potential data. In Figure 6 the HA-Lacto, with a z potential of −30 mV compared to HA alone, with values of −15 mV, show a strong aggregation of HA nanocrystals. The HA-Lacto-Que complex shows a positive z potential (11 mV), which demonstrates that the positive electrostatic surface potential of Que produces a strong surface interaction with the HA nanocrystals and stabilizes the previous HA-Lacto bond, which suggests less repulsion between the components of the complex [14] . This result is confirmed by independent z-potential data. In Figure 6 the HA-Lacto, with a z potential of −30 mV compared to HA alone, with values of −15 mV, show a strong aggregation of HA nanocrystals. The HA-Lacto-Que complex shows a positive z potential (11 mV) , which demonstrates that the positive electrostatic surface potential of Que produces a strong surface interaction with the HA nanocrystals and stabilizes the previous HA-Lacto bond, which suggests less repulsion between the components of the complex [14] . 

The human macrophage cell line U93 upon incubation after 6 h with Pseudomonas fluorescens displayed activation of the pro-inflammatory cytokines TNF-α, IL6, and IL8 ( Figure 7) . Instead, when the same cell line was incubated with the complexes or the single components, we observed a significant reduction of cytokine production. The experiment confirms, once more, the synergistic activity of the complex (HA-Lacto-Que). IL8 is the only cytokine that shows a marked difference in the presence of Lacto (4.08 Fc) or Que (11.74 Fc) . In other words, IL8 is down regulated when Que is more exposed on a complex surface. 

The human macrophage cell line U93 upon incubation after 6 h with Pseudomonas fluorescens displayed activation of the pro-inflammatory cytokines TNF-α, IL6, and IL8 ( Figure 7) . Instead, when the same cell line was incubated with the complexes or the single components, we observed a significant reduction of cytokine production. The experiment confirms, once more, the synergistic activity of the complex (HA-Lacto-Que). IL8 is the only cytokine that shows a marked difference in the presence of Lacto (4.08 Fc) or Que (11.74 Fc) . In other words, IL8 is down regulated when Que is more exposed on a complex surface. This result is confirmed by independent z-potential data. In Figure 6 the HA-Lacto, with a z potential of −30 mV compared to HA alone, with values of −15 mV, show a strong aggregation of HA nanocrystals. The HA-Lacto-Que complex shows a positive z potential (11 mV) , which demonstrates that the positive electrostatic surface potential of Que produces a strong surface interaction with the HA nanocrystals and stabilizes the previous HA-Lacto bond, which suggests less repulsion between the components of the complex [14] . 

The human macrophage cell line U93 upon incubation after 6 h with Pseudomonas fluorescens displayed activation of the pro-inflammatory cytokines TNF-α, IL6, and IL8 ( Figure 7) . Instead, when the same cell line was incubated with the complexes or the single components, we observed a significant reduction of cytokine production. The experiment confirms, once more, the synergistic activity of the complex (HA-Lacto-Que). IL8 is the only cytokine that shows a marked difference in the presence of Lacto (4.08 Fc) or Que (11.74 Fc) . In other words, IL8 is down regulated when Que is more exposed on a complex surface. 

Pseudomonas fluorescens is an opportunistic, psychotropic pathogen that can live in different environments, such as plant, soil, or water surfaces. Pseudomonas fluorescens has enzymes acting on proteins, lecithin, and lipids conferring to the aliment an undesirable taste [38] . Further, Pseudomonas fluorescens damages several plants causing chlorotic and necrotic lesions on leaves and fruits, with heavy economic losses to the agriculture and the food industry. The chemical additives, at present used to preserve the food against the pathogens, are perceived unhealthy by the consumer.

This study provides clear evidence that the bovine lactoferrin and the quercetin glycoside act against Pseudomonas fluorescens efficiently. Provided that data reported in literature are generally difficult to compare, our results (antimicrobial activities of lactoferrin and quercetin equal or up to 300 ppm) (Figure 1a ) agree with the literature [39, 40] . However, when the two molecules were combined, the MIC dropped to 200 ppm (Figure 2 ).

In the next step, the two molecules (Lacto and que) were combined with HA. The MIC dropped further down to 100 ppm (Figure 3a) . The best results were obtained when Lacto was added first to HA (Figure 3b ). One more positive feature emerging from our data is that Que and Lacto are completely adsorbed to HA (Figure 4a ,b) and the complex is stable, with a z-potential value of 11 mV ( Figure 6 ). The z-potential measures the repulsive forces between particles: the higher is the repulsive force, the lower is the probability of aggregate formation. Moreover, to assess if the effect induced by the simultaneous treatment with the HA-Lacto-Que and HA-Que-Lacto were additive or synergistic were analyzed two parameters: normalization as a function of control absorbance ( ); and synergistic coefficient (C syn ). Since high C syn values indicate a clear synergistic effect, the best result was obtained when the antimicrobial treatment was performed using HA-Lacto-Que complex (Table 1) .

Pseudomonas fluorescens is generally considered as non-pathogenic for humans. However, this pathogen has been detected in human clinical samples and shown to be highly hemolytic and able to induce cytotoxic and pro-inflammatory response [41] . An antigen from the same pathogen has been isolated from the serum of patients with Crohn's disease [42] .

Back to our study, in order to evaluate in vitro the anti-inflammatory activity of the complex, we infect the human macrophage cell line U937 with Pseudomonas fluorescens. We noticed a statistically significant reduction of several pro-inflammatory cytokines (Figure 7) . The high level of IL8 may be assigned to the presence of intracellular bacteria not killed by the Lacto (known to have a moderate antimicrobial activity) [43] . In the presence of que, IL8 is down regulated. This result is in line with the known activation of IL8 through the TLR4-independent pathway [44] . From this result, we can also infer that Que is not induced by LPS, a TLR4-dependent pathway. Consequently, the down regulation of IL8 reported above can appropriately be attributed to the presence of Que exposed on the complex (HA-Lacto-Que).

In conclusion, the peculiarity of our study consists of optimizing the specific propriety of each component: the affinity of Lacto for LPS; that of Que for the bacterial membrane, a property that we amplified by adding Que to the complex last and, therefore, more exposed ( Figure 8 ). These properties make the complex as good candidate for antimicrobial use in the food industry, and as functional food.

. 

The bacterial strains of Pseudomonas fluorescens strain ATCC 13525 were provided from the "Istituto Zooprofilattico Sperimentale del Mezzogiorno" in Portici (Naples, Italy). Pseudomonas fluorescens was grown overnight at 37 °C in the liquid culture medium (Buffered peptone water, BPW). To identify bacterial growth phase, turbidity of medium was measured by optical density measurement at 600 nm on a UV/Vis spectrophotometer.

Quercetin glycoside compound (98.6% food grade) was purchased from Oxford ® Vitality Company (Bicester, UK) and lactoferrin (95% food grade) from Fagron the UK. The stock solution of each compound was dissolved in water, to obtained a final concentration of 1 mg/mL.

The minimal inhibitory concentration (MIC) of each compound was determined by a colorimetric method, using 3-4,5-dimethylthiazol 2,5-diphenyltetrazolium bromide solution (MTT), using the standard broth microdilution method according to [33] . All antimicrobial tests performed in this work were carried out using the same method.

Biomimetic hydroxyapatite nanocrystals were produced as described by [45] . HA was precipitated from a solution of (CH3COO)2Ca (75 mM) by the slow addition of an aqueous solution of H3PO4 (50 mM) and maintaining pH at 10 (addition of NH4OH). The synthesis was carried out at room temperature (RT). Finally, the suspension of HA was 

The bacterial strains of Pseudomonas fluorescens strain ATCC 13525 were provided from the "Istituto Zooprofilattico Sperimentale del Mezzogiorno" in Portici (Naples, Italy). Pseudomonas fluorescens was grown overnight at 37 • C in the liquid culture medium (Buffered peptone water, BPW). To identify bacterial growth phase, turbidity of medium was measured by optical density measurement at 600 nm on a UV/Vis spectrophotometer.

Quercetin glycoside compound (98.6% food grade) was purchased from Oxford ® Vitality Company (Bicester, UK) and lactoferrin (95% food grade) from Fagron the UK. The stock solution of each compound was dissolved in water, to obtained a final concentration of 1 mg/mL.

The minimal inhibitory concentration (MIC) of each compound was determined by a colorimetric method, using 3-4,5-dimethylthiazol 2,5-diphenyltetrazolium bromide solution (MTT), using the standard broth microdilution method according to [33] . All antimicrobial tests performed in this work were carried out using the same method.

Biomimetic hydroxyapatite nanocrystals were produced as described by [45] . HA was precipitated from a solution of (CH 3 COO) 2 Ca (75 mM) by the slow addition of an aqueous solution of H 3 PO 4 (50 mM) and maintaining pH at 10 (addition of NH 4 OH). The synthesis was carried out at room temperature (RT). Finally, the suspension of HA was washed with distilled water to remove ammonium ions and favor the interaction between nanocrystals.

HA-Que and HA-Lacto complexes were prepared adding HA solution diluted (1:100) (4% w/v) with known concentrations (500, 400, 300, and 200 ppm) of Que or Lacto, respectively. The complexes were gently mixed at room temperature for 24 h. After the incubation, the solutions were centrifuge and the supernatants and the effective amount of Que and Lacto entrapped into the structure were measured. Specifically, the amount of Que was evaluated using UV-vis spectrophotometer (Perkin Elmer Lambda 25) at a wavelength of 369 nm; the standard curve consisted of 10-200 ppm Quercetin-3 glucoside. The amount of Lacto was evaluated using spectrophotometer Nanodrop ONE C at a wavelength of 280 nm and the standard curve consisted of 10-500 ppm BSA (Bovine Serum Albumin). Finally, the complexes HA-Que and HA-Lacto were vacuum evaporated for 2 h, then the second molecule-Que or Lacto (2000-100-50 ppm)-was added; finally, the complexes were mixed for 24 h and their antimicrobial activity was evaluated.

The additive or synergistic interaction of each complex was calculated using the parameters (normalization as a function of control absorbance) and Csyn (synergistic coefficient) statistical approach:

Once defined, the parameter was: a = 1 − (abs ctrl − abs a )/abs ctrl (1) It was possible to estimate the synergistic coefficient Csyn as:

Error analysis was performed according to [46] . Moreover, the FIC index can be used to confirm the effect of a tested combination. The FIC is designed by division of the MIC of the complex and the MIC of the molecules alone according to the following formula: (3)

The dimensions of HA, HA-Lacto, and HA-Lacto-Que were measured with the zeta potential using a Zetasizer Nano ZS (Malvern Instruments, DTS1070, Malvern, UK). Each sample was tested in triplicate using 1 mL of sample at 25 • C.

Water suspensions of HA, HA-Que, HA-Lacto, and HA-Lacto-Que samples were centrifuged at 13,000 rpm for 15 min and then deposited on 5 × 5 mm silicon chips; the solvent was evaporated under vacuum at 30 • C; the silicon supports were mounted as described in [46] . SEM microscopy was recorded with a NovaNanoSem 450 field emission gun scanning electron microscope (FEGSEM) (FEI/Thermofisher, Hillsboro, OR, USA), under high-vacuum conditions.

To further confirmed the synergistic activity of the complexes, the effect of HA-Lacto, HA-Que, HA-Lacto, and HA-Que-Lacto on human macrophage-like (U937) cell line, after 6 h of Pseudomonas fluorescens infection was carried out. The cells were maintained in RPMI supplemented with 10% FBS, 1% of Pen/strep, and cultured in 5% CO 2 atmosphere. For infection, U937 cells were seeded onto 12-well plates at a density of 0.5 × 10 6 cells/well, without antibiotics. Subsequently, the cells were infected with Pseudomonas fluorescens strains at a multiplicity of infection (MOI) of 100 with or without different treatment for 6 h. After the incubation period, the cells centrifuged for 5 min at 1500 rpm. The supernatant was discarded and the RNA was extracted using Trizol protocol [47] . A Nan-oDrop One/One C Microvolume UV-Vis Spectrophotometer (Thermo Fisher Scientific Inc., Waltham, MA, USA) was used to assess total RNA quantity. The retro-transcriptase was performed in order to synthetize first-strand cDNA (SuperScript ® III Reverse Transcriptase, Invitrogen). Real-time PCR reactions were carried out in triplicate; expression values were calculated according to the 2 −∆∆Ct method [48] , and all samples were normalized to GAPDH as a housekeeping gene. A negative sample (cell untreated) was used as calibrator. 

Identities of the Pseudomonas spp. in flora from chilled chicken

In vitro inhibition of food spoilage and foodborne pathogenic bacteria by essential oil and leaf extracts of Magnolia liliflora Desr

Residential Refrigerator Performance Based on Microbial Indicators of Ground Beef Preservation Assessed Using Predictive Microbiology Tools

Psychrotrophs in dairy products: Their effects and their control

Screening for differences in the proteolytic systems of Lactococcus, Lactobacillus and Propionibacterium

Pseudomonas fluorescens: A potential food spoiler and challenges and advances in its detection

Genetic diversity and spoilage potentials among Pseudomonas spp. isolated from fluid milk products and dairy processing plants

Combining antimicrobials and hydrodynamic pressure processing for control of listeria monocytogenes in frankfurters

Organic acids and their salts as dipping solutions to control Listeria monocytogenes inoculated following processing of sliced pork bologna stored at 4 • C in vacuum packages

Antimicrobial and antioxidant effects of sodium acetate, sodium lactate, and sodium citrate in refrigerated sliced salmon

Production and characterization of medium-sized and short antioxidant peptides from soy flour-simulated gastrointestinal hydrolysate

Identification and antimicrobial activity of medium-sized and short peptides from yellowfin tuna (Thunnus albacares) simulated gastrointestinal digestion

The Impact of Food Bioactives on Health: In Vitro and Ex Vivo Models

Multifunctional nanocomposite active packaging materials: Immobilization of quercetin, lactoferrin, and chitosan nanofiber particles in gelatin films

Antioxidant activities of quercetin and its complexes for medicinal application

Purification, characterization and antioxidant activities in vitro of polysaccharides from Amaranthus hybridus L

Antioxidant properties of several tropical fruits: A comparative study

Quercetin: Its Main Pharmacological Activity and Potential Application in Clinical Medicine

Bacteriostatic effect of quercetin as an antibiotic alternative in vivo and its antibacterial mechanism in vitro

Flavonoid analyses and antimicrobial activity of various parts of Phaleria macrocarpa (Scheff. ) Boerl fruit

Characterization of quercetin binding site on DNA gyrase

Anti-biofilm activities of quercetin and tannic acid against Staphylococcus aureus

Antibacterial activity of lactoferrin and a pepsin-derived lactoferrin peptide fragment

Studies on the Interaction between Three Small Flavonoid Molecules and Bovine Lactoferrin

In vivo quercitrin anti-inflammatory effect involves release of quercetin, which inhibits inflammation through down-regulation of the NF-κB pathway

Quercetin inhibits expression of inflammatory cytokines through attenuation of NF-κB and p38 MAPK in HMC-1 human mast cell line

Structure and association of human lactoferrin peptides with Escherichia coli lipopolysaccharide

Reciprocal interactions between lactoferrin and bacterial endotoxins and their role in the regulation of the immune response

Nanoencapsulation of bovine lactoferrin for food and biopharmaceutical applications. Food Hydrocoll

Can food and food supplements be deployed in the fight against the COVID 19 pandemic?

Biomimetic hydroxyapatite nanocrystals are an active carrier for salmonella bacteriophages

Biomimetic Nanostructured Apatitic Matrices for Drug Delivery

Development of a Novel Active Edible Coating Containing Hydroxyapatite for Food Shelf-life Extension

Biological activity of lactoferrin-functionalized biomimetic hydroxyapatite nanocrystals

The minimum inhibitory concentration of antibiotics: Methods, interpretation, clinical relevance

Techniques for the assessment of in vitro and in vivo antifungal combinations

Lipid-Based Nanoparticles for Drug Delivery Systems

Characterisation of the thermostable protease AprX in strains of Pseudomonas fluorescens and impact on the shelf-life of dairy products: Preliminary results

Antibacterial Activity of Some Flavonoids and Organic Acids Widely Distributed in Plants

Lactoferrin adsorbed onto biomimetic hydroxyapatite nanocrystals controlling-In Vivo-The Helicobacter pylori infection

THP-1 and U937

Microbiology, genomics, and clinical significance of the Pseudomonas fluorescens species complex, an unappreciated colonizer of humans

Lactoferrin downregulates pro-inflammatory cytokines upexpressed in intestinal epithelial cells infected with invasive or noninvasive Escherichia coli strains

Involvement of epidermal growth factor receptor-linked signaling responses in Pseudomonas fluorescens-infected alveolar epithelial cells

Amino acid synergetic effect on structure, morphology and surface properties of biomimetic apatite nanocrystals

The union is strength: The synergic action of long fatty acids and a bacteriophage against xanthomonas campestris biofilm

Purification of RNA Using TRIzol (TRI Reagent)

Analysis of Relative Gene Expression Data Using Real-Time Quantitative PCR and the 2 −∆∆CT Method

The data presented in this study are available within the article.

The authors declare no conflict of interest.