Enhancement of Antifungal Activity of Juglone (5-Hydroxy-1,4

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Enhancement of Antifungal Activity of Juglone (5-Hydroxy-1,4Naphthoquinone) Using PLGA Nanoparticles System Tulin Arasoglu, Banu Mansuroglu, Serap Derman, Busra Gumus, Busra Kocyigit, Tayfun Acar, and Ismail Kocacaliskan J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.6b03309 • Publication Date (Web): 07 Sep 2016 Downloaded from http://pubs.acs.org on September 7, 2016

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Journal of Agricultural and Food Chemistry is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.

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(A) The particle size distribution of JNP5 179x134mm (300 x 300 DPI)

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(B) The zeta-potential distribution of JNP5 184x131mm (300 x 300 DPI)

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(C) The SEM image of JNP5 76x58mm (220 x 220 DPI)

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(D) time-dependent release pattern of free juglone (square) and JNP5 (circle) 237x177mm (300 x 300 DPI)

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(E) FT-IR spectrums of Juglone, free NP and JNP5. 741x584mm (96 x 96 DPI)

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According to agar dilution method, the petri images of growth inhibition effects of juglone-PLGA nanoparticles and free juglone due to MIC values of JNP5 (250 µg/mL, 31.25 and 62.5 for A. flavus, C. albicans and Fusarium spp. respectively ) in the agar dilution method. (a) control, (b) JNP5, (c) Free juglone 137x140mm (96 x 96 DPI)

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The petri images of growth inhibition effects of juglone-PLGA nanoparticles and free juglone due to MIC values of JNP5 (125 µg/mL, 62.5 and 31.25 for A. flavus, C. albicans and Fusarium spp. respectively ) in the top agar dilution method (a) control, (b) JNP5, (c) Free juglone 145x140mm (96 x 96 DPI)

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Graphical abstract 357x152mm (96 x 96 DPI)

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Enhancement of Antifungal Activity of Juglone (5-Hydroxy-1,4-Naphthoquinone) Using

2

PLGA Nanoparticles System

3 4 5

Tulin Arasoglu†, Banu Mansuroglu†, Serap Derman‡,*,

6

Busra Gumus†, Busra Kocyigit†, Tayfun Acar‡ and Ismail Kocacaliskan†,

7 8



9

Department, 34220, Istanbul/Turkey

Yildiz Technical University, Science and Letters Faculty, Molecular Biology and Genetics

10



11

34220, Istanbul/Turkey

Yildiz Technical University, Chemical and Metallurgy Faculty, Bioengineering Department,

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ABSTRACT

28 29

In this study, it was aimed to synthesize and characterize juglone entrapped PLGA

30

nanoparticle and compare the antifungal properties of free juglone with its PLGA nanoparticle

31

formulation for the first time in the literature. The juglone loaded nanoparticles prepared

32

using the oil-in-water (o-w) single-emulsion solvent evaporation method were characterized

33

by the reaction yield (RY), encapsulation efficiency (EE), polydispersity index (PDI), particle

34

size, zeta potential (ZP), FT-IR, in vitro release properties and evaluated their morphological

35

features using SEM. The nanoparticle formulation had a size, RY, ZP, EE and PDI value of

36

212 nm, 66.91 ± 2.4 %, −16.3 ± 0.7 mV, 70.66 ± 3.1 % and 0.083 ± 0.024 respectively. In

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vitro release showed triphasic pattern with initial burst followed by sustained release and

38

dormant phase over the study period, total releasing about 72.8 % after 42 days. The

39

antifungal studies against A.flavus, C. albicans and Fusarium spp. using agar dilution and top

40

agar dilution methods indicated that the juglone encapsulated nanoparticle was more effective

41

than free juglone. In this study, it is showed that the top agar method which applied for the

42

first time on the antifungal activity is more suitable for the nanoparticular system based on

43

sustained release. So that, the PLGA nanoparticle formulations may be an important tool for

44

application in many areas from the point of the effective and beneficial use for hydrophobic

45

compounds such as juglone.

46 47

Keywords

48

5-hydroxy-1,4-naphthoquinone, Juglone, nanoparticle, antifungal activity

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INTRODUCTION

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Allelopathy is direct or indirect, harmful or beneficial effect of a plant on other plants, insects

55

and microbes due to chemical compounds synthesized and secreted into the environment.

56

These compounds are called as allelochemicals and they can usually be found in every tissue

57

of a plant, especially in leaves and roots. These compounds are released into the environment

58

through volatilization, water contact, exudation from root and plant residues. Allelochemicals

59

can have effects on cell division, respiration, photosynthesis, membrane permeability, protein

60

synthesis and seed germination 1, 2.

61

Juglone is an allelochemical that is located in the naphthoquinone subgroup within the

62

quinones, and a secondary metabolite produced by the walnut tree (Juglandaceae)3. Juglone is

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selectively toxic towards some animals, microorganisms and plants and has been used for

64

many other purposes through long ages

65

other organisms but not the plant itself, Duroux et al. reported that this compound is also

66

necessary for the plant development7. Besides, it was reported that juglone has anticancer 8, 9,

67

cytotoxic and genotoxic

68

antifungal

69

poor dissolution property due to its hydrophobic character.

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In order to provide sustained release of active substances, polymers that convert into nontoxic

71

metabolites are usually preferred

72

polyglycolic acid (PGA) and copolymer of these, poly (d,l-lactic-co-glycolic acid) (PLGA)

73

are most commonly used to synthesize active substance encapsulated nanoparticle systems to

74

provide sustained release 26-30. PLGA, one of the FDA approved biopolymers used frequently

75

for drug delivery systems, was an appropriate carrier to prepare nanoparticle systems with

76

substances soluble in water or oil 31. In recent years, the use of nanoparticle systems produced

20-24

10, 11

4-6

. Although it was thought that juglone only affects

, antioxidant

9, 12-15

, antiviral

16

, antibacterial

8, 9, 14, 17-20

and

effects. However, its application and bioavailability is limited because of its

25

. Biodegradable polymers such as polylactic acid (PLA),

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by encapsulating antimicrobial agents into PLGA biopolymer has become very prevalent.

78

Thus;

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biocompatibilities of these agents increased remarkably in comparison with the free form of

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the same drug 32, 33. Additionally, nanotechnology studies on developing antifungal agents are

81

still in the early stages and there is an urgent need for the development of eco-safe fungicides.

82

Bionanomaterials are a promising alternative with high efficacy and relevant cost34. Due to

83

their high surface to volume ratio and small size; they can surpass the physiological barriers,

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reach the target and interact well with the pathogens. Although the introduction of

85

nanomaterials to the field is recent, it has already been agreed that the use of bionanomaterials

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are a necessity for defeating resistant pathogenic organisms 35.

87

In the literature, researches about the antifungal activity of juglone compound are few in

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number; but instead, a large number of studies published about walnut tree extracts. In our

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research, we aimed to encapsulate juglone molecule into PLGA nanoparticle system for the

90

first time and to evaluate its antifungal activity comparatively with free juglone. It should be

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stated that this is the first research in the literature about the antifungal activity of juglone

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encapsulated PLGA nanoparticles. To assess this antifungal activity, two different methods

93

were used and compared against Aspergillus flavus, Candida albicans and Fusarium spp.

it

was

stated

that

pharmacokinetics

properties,

therapeutic

indexes

and

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METHODS

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Preparation of Nanoparticles

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In this study, juglone, PVA, PLGA (lactide:glicolide = 50:50; inherent viscosity 0.45-0.60

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dL/g, Mw ~ 38-54 kDa P50/50), and DCM were purchased from Sigma Aldrich (St. Louis,

99

USA). The modified single emulsion solvent evaporation method was used for preparation of 36, 37

100

Juglone loaded PLGA nanoparticles which described by our previous studies

101

Juglone (50 mg/mL) and PLGA (40 mg/mL) were firstly dissolved in water immiscible DCM,

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mixed together then suitably stirred to ensure that all materials were dissolved. This mixture

103

was emulsified with aqueous PVA solution (3 % w/v), over an ice bath, using microtip probe

104

sonicator (output power 100 W, power of % 80 and 2 minutes, Bandelin Sonopuls, Germany).

105

The obtained o/w single emulsion was then diluted in 35 mL of PVA solution (0.1 % w/v) and

106

left on magnetic stirring for overnight at room temperature. The nanoparticles were collected

107

by centrifugation at 12.000 x rpm for 40 minutes (Beckman Coulter, Allegra-X-30R) and

108

washed three times with ultra-pure water then the obtained suspensions were lyophilized. The

109

free nanoparticles were prepared with similar method without using Juglone and lyophilized

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nanoparticles were stored at -80 °C until used.

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Characterization of Nanoparticles

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The reaction yield and encapsulation efficiency of nanoparticles were determined in triplicate.

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The reaction yield was calculated gravimetrically as follow 36.

114

 % =

115

The indirect quantification method was used to analyze encapsulation efficiency of

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nanoparticles using UV-Vis Spectroscopy at 424 nm in triplicate. The juglone concentration

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in the supernatant was determined by using previously constructed standard calibration curve.

118

The encapsulation efficiency of juglone was calculated as follow:

119

 % =

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Both zeta potential (ζ) and mean diameter of particles were analyzed using a Zetasizer

121

(Zetasizer Nano ZS, Malvern, UK) instrument with electrophoretic light scattering (ELS) and

122

dynamic light scattering (DLS) techniques, respectively 38.

123

Morphology and FT-IR Study of Nanoparticles

124

Scanning electron microscopy (SEM, A JSM-7001FA, Jeol, Japan) was used to observe the

125

shape and surface morphology of produced nanoparticles as previously described in our

126

studies

 

             

 100

           

      

 100

36

(1)

(2)

. Lyophilized nanoparticles were fixed on metallic studs using adhesive tapes and 5 ACS Paragon Plus Environment

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then coated with gold under vacuum. SEM photomicrographs were taken at an acceleration

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voltage of 10–30 kV.

129

FT-IR (Fourier Transform Infrared Spectroscopy) measurements were carried out by IR-

130

Prestige 21 FTIR spectrophotometer (Shimadzu, Japan) in ATR mode

131

ranging between 600 cm-1 and 4000 cm-1 were obtained with resolution of 4 cm−1.

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Release Study

133

The in vitro drug release study was carried out in triplicate using modified dissolution method

134

36

135

saline) and incubated 37 °C in a shaking incubator (150 rpm) at pH 7.4. At specified time

136

interval, the samples were centrifuged at 9000 rpm for 20 minutes, then the supernatant was

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collected and the precipitates were suspended with 2 mL of fresh PBS. The juglone

138

concentration in the supernatant was determined with UV-Vis Spectroscopy at 424 nm by

139

comparing the concentration to a previously constructed standard calibration curve.

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Determination of Antifungal Activities of Free Juglone and Synthesized Nanoparticles

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The antifungal activity of free juglone and juglone-PLGA-NPs were assessed by the agar

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dilution method, according to the recommendations of the National Committee for Clinical

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Laboratory Standards 39, and top agar dilution method which was applied for the first time in

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this study. Two methods were performed separately for Candida albicans (ATCC 10231),

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Aspergillus flavus (ATCC 204304) and Fusarium spp.(ATCC 20883) (provided by

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Bacteriological Laboratory, Faculty of Science, at Ataturk University, Erzurum, Turkey).

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Three different fungi isolates were subcultured at 27 oC on Sabouraud Dextrose Agar with

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2 % dextrose (SDA- from Dıfco, BD Diagnostic Systems, United States) until good growth

149

was obtained. Spores were harvested in 5 mL Sabouraud Dextrose Broth (SDB- from Dıfco,

150

BD Diagnostic Systems, United States) and the tubes were incubated at 27 oC for three days.

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After the incubation period, the tubes were centrifuged at 5000 rpm for 8 minutes. The pellet

36

. The FTIR spectra

. Juglone-PLGA-NPs (5 mg) were suspended in 2 mL of 150 mM PBS (phosphate buffer

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was washed three times in 0.01 M sodium phosphate buffer (pH 7.4), resuspended in PBS.

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The spore suspensions in buffer were then adjusted spectrophotometrically to 78-82 %

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transmittance for C. albicans and 68-70 % transmittance for Fusarium spp. and A. flavus at a

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wavelength of 600 nm 40. These suspensions were used in the top agar method.

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Agar Dilution Method

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This method involves the incorporation of varying desired concentrations of the antifungal

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agent into a molten agar medium, followed by the inoculation of fungal cultures onto the agar

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plate surface. The minimum inhibition concentration (MIC) value was determined as the

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lowest concentration of antifungal agent that inhibits growth after incubation time. The

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minimum fungicidal concentration (MFC) was regarded as the lowest concentration doesn’t

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yield any fungal growth on the solid medium used. Briefly, appropriate amounts of the free

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juglone and the juglone-PLGA-NPs were dissolved in sterile distilled water and added

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aseptically into sterile molted SDA medium, ending up with a concentration range of 15.33-

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500 µg/mL. The resulting SDA mediums were immediately poured into Petri plates after

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vortexing. Small blocks of agar (2x2 mm) from growing fungal cultures were cut and placed

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on the SDA plates. The inoculated plates were incubated at 27 oC for seven days. At the end

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of the incubation period, the plates were evaluated for the presence or absence of fungal

169

growth. In this study, two control plates were used: the first one containing only fungal

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culture, the latter containing empty nanoparticles and fungal culture. Each test was repeated

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three times.

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Top Agar Dilution Method

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Top agar dilution method has been developed by modeling AMES method

174

(Salmonella/microsome assay) for this study. In this method, the fungal spores were directly

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exposed to the test chemical for a certain time in a sterile tube containing buffered medium.

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Then, it was spread over the surface of SDA after adding the molten top agar into the same

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tube. The most important point in the use of this method is the direct interaction between the

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test substance and the tested organism for a short period or preincubation time. The antifungal

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activity was examined according to the fungal growth on the plates.

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In the top agar method; the stock solutions were prepared by dissolving of the free juglone

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and the juglone-PLGA-NPs in sterile distilled water (1.38 mg/mL for the free juglone; 5

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mg/mL for the juglone-PLGA-NPs, containing the same amount of active ingredient with free

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juglone). Six different concentrations for each material were prepared (500 µg/mL, 250

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µg/mL, 125 µg/mL, 62.5 µg/mL, 31.25 µg/mL, 15.33 µg/mL) and distributed to the sterile

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tubes. After that, 100 µL of the fungal cultures (prepared as mentioned above) was added into

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the tubes and the tubes were preincubated for 30 minutes. Finally, the tubes were shaken

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gently by adding 2 mL of molten top agar containing 0.5 mM NaCl and the mixtures were

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poured and spreaded quickly onto the plates containing SDA. After incubation at room

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temperature for 7 days, the antifungal activity was evaluated based on the presence or absence

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of fungal growth. Two control plates were included in each test run. One control plate

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contained only fungal culture; and the other one contained the free PLGA nanoparticles

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dissolved in sterile distilled water, in addition to the molten top agar. Each test was repeated

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three times.

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RESULTS

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Nanoparticle Preparation and Characterization

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The o/w single-emulsion solvent evaporation method was used for the preparation of free and

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juglone loaded nanoparticles. The juglone-PLGA-NPs were analyzed for R.Y., E.E., Z-Ave,

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PDI and Z.P.

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After weighing of nanoparticles, the reaction yield was calculated to 50.47 ± 2.6 % and 66.91

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± 2.4 % for free nanoparticles and juglone-PLGA-NPs, respectively. The encapsulation

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efficiency of Juglone was calculated as 70.66 ± 3.1 % using indirect method.

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Table 1. R.Y., E.E., Z-Ave, PDI and Zeta potential of nanoparticles (JNP5)

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Particle Size, Zeta Potential and Polydispersity of Nanoparticles

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The particle size and zeta potential of nanoparticles were measured using dynamic and

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electrophoretic light scattering, respectively. Figure 1 shows particle size (A) and zeta

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potential (B) distribution of juglone-PLGA-NPs. The Z-average of nanoparticles were

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measured as 183.1 ± 1.35 nm and 212.2 ± 4.65 nm for free nanoparticles and juglone-PLGA-

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NPs, respectively. It was seen that the mean diameter of juglone-PLGA-NPs increased up to

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212.2 ± 4.65 nm by encapsulation of juglone. Both Z-Ave of the nanoparticles were measured

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less than 220 nm in diameter with monodisperse size distribution. As known, the smaller

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particle size (100-250 nm) is required for the high cellular uptake of nanoparticles

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formulations were part of a single population (100 % intensity) and had low values of

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polydispersity (0.092 ± 0.020, and 0.083 ± 0.024) which indicates the uniformity of particle

216

size.

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Results of the zeta potential measurement of nanoparticles were shown in Table 1. Free

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nanoparticles and juglone-PLGA-NPs showed negative zeta potential values which indicate

219

the stable state of nanoparticles owing to electrostatic repulsion 44. In the present study, free

220

juglone and juglone-PLGA-NPs had -23,6 ± 1.6 mV and -16.3 ± 0.7 mV, respectively due to

221

the use of nonionic emulsifier PVA

222

negative zeta potential provides the nanoparticle suspensions to be stable by preventing the

223

agglomeration of nanoparticles 36, 47.

45

43

. All

and the terminal carboxylic group of polymer 46. This

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Figure 1. (A) The particle size distribution of JNP5, (B) zeta-potential distribution of JNP5,

226

(C) SEM image of JNP5, (D) time-dependent release pattern of free juglone (square) and

227

JNP5 (circle) and (E) FT-IR spectrums of Juglone, free NP and JNP5.

228 229

Morphology and FT-IR Study of Nanoparticles

230

The image of juglone-PLGA-NPs was observed using SEM as shown in Figure 1 C. The

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nanoparticles had smooth texture of surface morphology, spherical topography and uniform

232

size distributions without any agglomeration. The SEM image is in good agreement with the

233

result measured by DLS, indicates clearly that the produced nanoparticles had narrow size

234

distribution.

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The FT-IR spectra of juglone, free nanoparticles and juglone loaded PLGA nanoparticles

236

were demonstrated in the Figure 1E. In the FT-IR spectra, absorption peaks are assigned to

237

specific functional groups. The pure juglone showed the main characteristic peak in the region

238

of 1665-1630 cm-1 due to carbonyl groups (C=O) and the other important peaks are C=C

239

stretching that is observed at 1592 cm-1 and C-O stretching which is observed at 1288 cm-1. It

240

is understood from the spectra of free NPs and JNP5 that the 1750 cm-1 peak is corresponding

241

to C=O group and the peaks between 1250-1100 cm-1 is due to C-O stretch of the PLGA

242

polymer. When the spectra of free NPs and JNP5 are compared, it is seen that specific

243

functional groups in the surface of JNP5 have almost the same chemical characteristics of the

244

free nanoparticles. The FT-IR spectra show that juglone was successfully encapsulated to

245

PLGA nanoparticles without having any physical or chemical interaction.

246

Release Study

247

On the other hand, the release study was performed in 150 mM PBS (pH 7.4). The results

248

presented in Figure 1 D show that free juglone was dissolved in the media within 48 h period.

249

Whereas, juglone loaded PLGA nanoparticles showed sustained triphasic release pattern up to

250

42 days. In vitro release profile of juglone-PLGA-NPs over 40 days shows that after 4 h, 10 ACS Paragon Plus Environment

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approximately 30 % of juglone had been released from nanoparticle which is indicative of

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initial burst release. Then, in the intermediate phase, the released juglone amount had

253

increased up to 69.9 % within the following 10 days. Next, the release became very slow and

254

the release curve slope reaches to a plateau corresponding to a maximum 72.8 % at the end of

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42 days.

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Antifungal Activity of Free Juglone and Synthesized Nanoparticles

257

In the agar dilution method, the antifungal activity of free juglone and juglone-PLGA-NPs

258

were evaluated on the basis of fungal growth. The MIC and MFC values are shown in Table

259

2. It was observed that the PLGA nanoparticle systems caused a remarkable decrease in MIC

260

values against C. albicans, Fusarium spp. Among the three fungal species, the lowest MIC

261

value of the juglone encapsulated PLGA nanoparticles were 31.25 µg/mL, while the

262

lowest MIC value of the free juglone was found 62.5 µg/mL against C. albicans. The MIC

263

value of the free juglone was determined as 125 µg/mL for Fusarium spp., whereas it was

264

twofold higher for the juglone-PLGA-NPs. According to the MFC values, the free juglone

265

was higher four times for C. albicans, two times for Fusarium spp than its nanoparticle

266

formulations. In the case of A. flavus, the MIC and MFC values for the juglone encapsulated

267

PLGA nanoparticles was obtained as 250 µg/mL, as did for the free juglone.

268 269

Table 2. The MFC and MIC values according to agar dilution method

270 271

Figure 2 shows the Petri images of the growth inhibition ratios between juglone-PLGA-NPs,

272

free juglone and control groups according to the MIC values detected for JNP5 by agar

273

dilution method against all strains. As shown in this figure, the growth difference between

274

juglone-PLGA-NPs and the free juglone for C. albicans and Fusarium spp. was slightly

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observed. Also, this difference appears to be much higher for both groups compared with the

276

control.

277 278

Figure 2. According to agar dilution method, the Petri images of growth inhibition effects of

279

juglone-PLGA nanoparticles and free juglone due to MIC values of JNP5 (250 µg/mL, 31.25

280

µg/mL and 62.5 µg/mL for A. flavus, C. albicans and Fusarium spp respectively ) in the agar

281

dilution method. (a) control, (b) Juglone-PLGA-NPs, (c) Free juglone

282 283

The top agar dilution method was performed by adding the molten top agar on fungal spores

284

being exposed directly to juglone and its nanoparticle formulation in the buffered medium for

285

a short time. In this method, the decrease in visible fungal growth was interpreted as

286

antifungal activity or fungicidal activity. According to our results, the MIC and MFC value of

287

free juglone was higher four times for C. albicans, four times for Fusarium spp. and two

288

times for A. flavus, when compared to the nanoparticle formulations (Table 3). The empty

289

NPs were evaluated as the control group showed no effect in both studies (data not shown).

290 291

Table 3. The MFC and MIC values according to top agar dilution method

292 293

In the Figure 3, strong visual evidence of growth inhibitiory effect was observed in the

294

juglone-PLGA-NPs exposed to Petri plates compared with both free juglone and control

295

groups in top agar dilution method.

296 297

Figure 3. The Petri images of growth inhibition effects of juglone-PLGA nanoparticles and

298

free juglone due to MIC values of JNP5 (125 µg/mL, 62.5 µg/mL and 31.25 µg/mL for A.

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flavus, C. albicans and Fusarium spp. respectively) in the top agar dilution method (a)

300

control, (b) JNP5, (c) Free juglone

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DISCUSSION

303

Fungal organisms cause a significant problem in health sector by developing antifungal

304

resistance mechanisms recently and in food industry by decreasing the food quality, quantity

305

and storage time 3. Therefore, there is an urgent need for exploring new antifungal agents that

306

can be used in both sectors. When the harmful effects of synthetically produced chemical

307

agents in human health considered, the demand for natural antifungal agents obtained from

308

plants increases gradually

309

antifungal agents 49. PLGA nanoparticle systems are widely used to improve the efficacy and

310

the impact time of natural bioactive compounds. Considering this situation, PLGA

311

nanoparticle systems are widely used to improve the efficacy and the impact time of natural

312

bioactive compounds in recent years

313

example gene therapy, targeted drug delivery, and the effective usage of active agents such as

314

seconder metabolites and pharmaceutical drugs. In antifungal treatments, a major concern

315

with currently available antifungal drugs is the low systemic bioavailability arising from low

316

aqueous solubility and early drug degradation. Keeping this in perspective, the present study

317

was aimed that the juglone loaded PLGA nanoparticle systems were successfully synthesized

318

using the oil-in-water single-emulsion solvent evaporation method, characterized in detailed

319

and evaluated its antifungal activity in comparison with free juglone. The antifungal activity

320

of the synthesized JNP5 was also evaluated by two different methods against Aspergillus

321

flavus, Candida albicans and Fusarium spp. for the first time in literature.

322

Juglone is a naphthoquinone synthesized in walnut tree and the antifungal properties of this

323

compound have been known for many years 3. When literature reviewed; it was observed that

48

. Also, plants are excellent resources for the supply of new

50

. Applications of PLGA-NPs are greatly broad, for

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the antifungal activity research about naphthoquinone derivatives are predominant

325

there are only a few studies about the juglone molecule 20. Although it was reported in these

326

research that juglone has an apparent antifungal activity, differences found between the MIC

327

values that was thought to be caused by reasons such as methods selected, solvents, juglone

328

source and fungal strains.

329

Furthermore; based on our knowledge, there was no reported data about the synthesis and

330

characterization of the juglone loaded PLGA nanoparticles and the evaluation of the

331

antifungal activity of the juglone encapsulated nanoparticles, as well. Therefore, in our study,

332

the antifungal activity of the juglone-PLGA NPs was evaluated for the first time in literature.

333

According to the our results, the juglone loaded PLGA nanoparticles proved to be more

334

effective in inhibiting fungal growth, when compared to free juglone by both methods used.

335

In former studies, it has also been shown that amphotericin b 54, voriconazole 55 and ITZ 56, 57

336

entrapped PLGA nanoparticles showed more potent antifungal efficacy than their free

337

formulations congruently. In our study, one of the main reason behind the enhancement in

338

antifungal activity may be the solubility increase of the hydrophobic juglone molecule which

339

provided by the encapsulation into the nanoparticle system.

340

Another important reason may be existence of chitin that is the main component of the fungal

341

cell wall structure. β-1,4- linked N-acetylglucosamine unites of the chitin provide a strong

342

positive charge to fungal cells. PLGA nanoparticles, due to their negative charge, form an

343

electrostatic interaction with the fungal cell walls. This situation provides the access of the

344

nanoparticles to the cell surfaces, their accumulation and later on, the entrance of the released

345

active substances or the nanoparticles into the cells and therefore increases the antifungal

346

activity by forming an electrostatic attraction between the organisms and the PLGA-NPs

347

Besides, the hydrophobins secreted by fungal organisms form an amphipathic membrane

348

structure and so provide contact between the hydrophilic medium and hydrophobic agents

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, but

58

.

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57

349

such as juglone due to their hydrophobic and hydrophilic regions

350

limited and the drug activity is low. In contrast to that; because of their hydrophilic structure,

351

the juglone loaded PLGA nanoparticles interact well with the fungal surfaces and reveal a

352

stronger growth inhibitory effect.

353

As reported in previous researches, it is easier for small sized particles to enter the cells and

354

the size of the juglone-PLGA nanoparticles synthesized in this study (212.2 ± 4.65 nm) is

355

within the range described as «small sized nanoparticle» in the literature 43, 57, 59. In addition to

356

these; despite the fact that the initial dose of the free juglone provides growth inhibition, drug

357

concentration decreases based upon the consumption or degradation by the spores as time

358

progresses. On the contrary, nanoparticle systems burst in first 4 hours (the moment when the

359

most of the active substance is released) and then continue to release active material in the

360

process of time. This continuous exposure prevents the regrowth of fungal spores and that

361

way provides a longer effect 57.

362

In the present study; we examined the antifungal activity of the free juglone and its

363

nanoparticle formulation by using two different methods: agar dilution and top agar dilution.

364

The effect of the time dependent release of the active material on the fungal organisms was

365

observed more specifically in the top agar dilution method due to the interaction occurred

366

between the fungal organisms and nanoparticles in the liquid medium for a while (30 minutes

367

– preincubation time). Moreover, it was thought that the effect of the pH change -caused by

368

this interaction- on the surface charges, has an effect again on the interaction itself as well 60.

369

It was also thought that the interaction time may be important for the method’s efficacy.

370

Because of that, further research will be performed to evaluate the correlation between the

371

antifungal activity and the interaction time in detail. Since the top agar dilution method allows

372

using far less material than the agar dilution method, it is planned to perform validation

15 ACS Paragon Plus Environment

. Still, this interaction is

Journal of Agricultural and Food Chemistry

373

studies to improve the methodology and provide the efficient usage of the method in release-

374

based nanoparticle systems.

375

In conclusion, the juglone’s antifungal activity improved by the entrapment into the PLGA

376

nanoparticle system has been shown visually in Petri plates of agar dilution and top agar

377

dilution methods (Figure 2 and 3). Moreover; in this study, more effective results were found

378

in the top agar dilution method which was used to detect the antifungal activity for the first

379

time in literature when compared to the agar dilution method. A stronger inhibition effect on

380

the fungal growth was observed clearly for the juglone-PLGA-NPs than the free juglone

381

molecules by the top agar method. This suggests increased sensitivity for the top agar dilution

382

method in the antimicrobial and antifungal activity studies of the PLGA nanoparticle systems,

383

particularly. Additionally, to provide a more detailed explanation of the enhanced antifungal

384

effect detected in this study, we suggest performing further in vivo and in vitro studies on the

385

cellular uptake mechanisms and the interactions between the juglone-PLGA-NPs and fungal

386

species.

387 388

ACKNOWLEDGEMENTS

389

The authors wish to express their thanks to TUBITAK for supplying the financial support

390

(project numbers; 114Z093). Also, the authors are grateful to Prof. Dr. Medine Güllüce and

391

Assistant Professor Dr. Zeynep Mustafaeva Akdeste for providing laboratory facilities.

392 393

AUTHOR INFORMATION

394

Corresponding Author;

395

Serap DERMAN (Ph.D)

396

Telephone: +090 212 483 4643 E-mail: [email protected]

397

16 ACS Paragon Plus Environment

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Journal of Agricultural and Food Chemistry

398

Funding

399

This research has been supported by TUBITAK, project numbers; 114Z093.

400

Notes

401

The authors declare no competing financial interest.

402 403

REFERENCES

404 405 406 407 408 409 410 411 412 413 414 415 416 417 418 419 420 421 422 423 424 425 426 427 428 429 430 431 432 433 434 435 436 437 438 439 440

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Journal of Agricultural and Food Chemistry

Tables

584 585

Table 1. R.Y., E.E., Z-Ave, PDI and Zeta potential of nanoparticles (JNP5)

586 Name

R.Y %

E.E %

Z-Ave (nm)

PDI

Z.P (mV)

Free NP

50.47 ± 2.6

-

183.1 ± 1.35

0.092 ± 0.020

-23.6 ± 1.6

212.2 ± 4.65

0.083 ± 0.024

-16.3 ± 0.7

Juglone NP

66.91 ± 2.4 70.66 ± 3.1

587 588 589

Table 2. The MFC and MIC values according to agar dilution method

Test samples

MFC values (µg/mL)

MIC values (µg/mL)

Fungal organisms

Fungal organisms

A. flavus C. albicans Fusarium spp. A. flavus C. albicans Fusarium spp.

Juglone-NPs

500

62.5

125

250

31.25

62.5

Free juglone

500

250

250

250

62.5

125

590 591

Table 3. The MFC and MIC values according to top agar dilution method

Test samples

MFC values (µg/mL)

MIC values (µg/mL)

Fungal organisms

Fungal organisms

A. flavus C. albicans Fusarium spp. A. flavus C. albicans Fusarium spp.

Juglone-NPs

250

125

62.5

125

62.5

31.25

Free juglone

>500

500

250

250

250

125

592 593 594 595 596 597 598 21 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

599

Figures

600

601

602

603 604 605

Figure 1. (A) The particle size distribution of JNP5, (B) zeta-potential distribution of JNP5,

606

(C) SEM image of JNP5, (D) time-dependent release pattern of free juglone (square) and

607

JNP5 (circle) and (E) FT-IR spectrums of Juglone, free NP and JNP5. 22 ACS Paragon Plus Environment

Page 30 of 32

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Journal of Agricultural and Food Chemistry

608

609 610

Figure 2. According to agar dilution method, the petri images of growth inhibition effects of

611

juglone-PLGA nanoparticles and free juglone due to MIC values of JNP5 (250 µg/mL, 31.25

612

and 62.5 for A. flavus, C. albicans and Fusarium spp respectively ) in the agar dilution

613

method. (a) control, (b) JNP5, (c) Free juglone

614

23 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

615 616

Figure 3. The petri images of growth inhibition effects of juglone-PLGA nanoparticles and

617

free juglone due to MIC values of JNP5 (125 µg/mL, 62.5 and 31.25 for A. flavus, C. albicans

618

and Fusarium spp respectively ) in the top agar dilution method (a) control, (b) JNP5, (c) Free

619

juglone

620

24 ACS Paragon Plus Environment

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