Microemulsification of clove essential oil improves its in vitro and in vivo control of Penicillium digitatum

Accepted Manuscript Microemulsification of clove essential oil improves its in vitro and in vivo control of Penicillium digitatum Shoukui He, Xiaoyun Ren, Yangfan Lu, Yunbin Zhang, Yifei Wang, Linjun Sun PII:

S0956-7135(16)30021-4

DOI:

10.1016/j.foodcont.2016.01.020

Reference:

JFCO 4830

To appear in:

Food Control

Received Date: 7 September 2015 Revised Date:

12 January 2016

Accepted Date: 13 January 2016

Please cite this article as: He S., Ren X., Lu Y., Zhang Y., Wang Y. & Sun L., Microemulsification of clove essential oil improves its in vitro and in vivo control of Penicillium digitatum, Food Control (2016), doi: 10.1016/j.foodcont.2016.01.020. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

ACCEPTED MANUSCRIPT 1

Microemulsification of clove essential oil improves its in vitro and in vivo control

2

of Penicillium digitatum

3

Running title: Microemulsion improves clove oil antifungal activity

5

RI PT

4 Shoukui He, Xiaoyun Ren, Yangfan Lu, Yunbin Zhang, Yifei Wang*, Linjun Sun

6

School of Perfume and Aroma Technology, Shanghai Institute of Technology, Haiquan

8

Road 100, Shanghai 201418, People’s Republic of China

M AN U

SC

7

9 *Correspondence

11

Yifei Wang, School of Perfume and Aroma Technology, Shanghai Institute of

12

Technology, Shanghai 201418, People’s Republic of China

13

Email: [email protected]

14

Tel.: +86 021 60873150

15

Fax: +86 021 60873248

EP

AC C

16

TE D

10

1

ACCEPTED MANUSCRIPT 17

Abstract: Clove essential oil (CEO) is a promising alternative to chemical fungicides for

19

postharvest decay control. However, relatively high concentrations required for in

20

vivo microbial growth inhibition limit its application. Hence, this study aimed to

21

strengthen the antifungal activity of CEO by loading it in microemulsion system. Two

22

CEO

23

CEO/ethanol/Tween 80 = 1:3:6) were evaluated their antifungal activity against

24

Penicillium digitatum in vitro and in navel oranges. Microemulsification of CEO

25

caused a reduction of MIC (minimum inhibitory concentration) from 0.50 µl/ml to

26

0.25 µl/ml, while the MFC (minimum fungicidal concentration) remained unchanged

27

at 0.50 µl/ml, indicating enhancement of only fungistatic activity. The decay

28

incidence of navel oranges treated with ME-1 and ME-2 was significantly (p < 0.05)

29

reduced by 34.51% and 20.93%, respectively, in comparison to that of pure oil

30

treatment after 5 days’ storage at 25 oC. In the vapor phase, CEO microemulsions had

31

the best control of lesion diameter and decay development. Additionally, the

32

improved antifungal activity of CEO microemulsions may be related to their stronger

33

ability to suppress spore germination and germ tube elongation of P. digitatum. The

34

enhanced control of postharvest green mold of navel oranges by CEO after

35

microemulsification can broaden its application in food industry.

36

Key words: clove essential oil; microemulsion; antifungal activity; navel oranges;

37

Penicillium digitatum

(ME-1,

CEO/ethanol/Tween

80

=

1:2:7;

ME-2,

AC C

EP

TE D

M AN U

SC

microemulsions

RI PT

18

38

2

ACCEPTED MANUSCRIPT 39

1. Introduction Navel oranges (Citrus sinensis L., Osbeck) are popular due to their highly

41

nutritional value. Unluckily, they are readily affected by pathogens (i.e., Penicillium

42

digitatum and Penicillium italicum) (Zeng, Zhang, Chen, & Fu, 2012). For citrus fruit,

43

green mold caused by P. digitatum accounts for 90% of postharvest losses (Kellerman,

44

Erasmus, Cronjé, & Fourie, 2014). Traditionally, chemical fungicides are primarily

45

utilized to control this disease. However, in consideration of antifungal resistance,

46

environmental problems and human toxicity (Xu, Yan, Ni, Chen, Zhang, & Zheng,

47

2014), natural antifungal products should be developed as alternatives.

M AN U

SC

RI PT

40

In recent years, environmentally friendly essential oils (EOs) have been

49

extensively studied as natural food preservatives due to their broad antimicrobial

50

activities (Davidson, Critzer, & Taylor, 2013). Since EOs can be derived from organic

51

plants, application of EOs is an appealing approach to control postharvest diseases. A

52

predominant defense mechanism of plants against pests and pathogens is believed to

53

be the production of EOs (Feng, & Zheng, 2007). Indeed, EOs of citronella (Chen et

54

al., 2014), Laurus nobilis (Xu, Yan, Ni, Chen, Zhang, & Zheng, 2014), lemongrass

55

and cinnamon (Maqbool, Ali, Alderson, Mohamed, Siddiqui, & Zahid, 2011) have

56

exhibited inhibitory activity against postharvest fungal pathogens in vitro and in vivo.

57

Despite the high efficiency of EOs in in vitro tests, the same effect in food is achieved

58

only with higher concentrations (Burt, 2004; Hulin, Mathot, Mafart, & Dufosse, 1998).

59

This fact may imply a challenging issue of EOs utilization in food industry, namely,

60

the balance between sensory acceptability and antifungal activity.

AC C

EP

TE D

48

3

ACCEPTED MANUSCRIPT There are increasing interest to formulate microemulsions for antimicrobial

62

applications. An ethyl oleate-based microemulsion system was active against five

63

foodborne pathogens (Teixeira, Leite, Domingues, Silva, Gibbs, & Ferreira, 2007).

64

Similarly, another research group found that a food-grade glycerol monolaurate

65

microemulsion was effective in inhibiting Bacillus subtilis, Escherichia coli and

66

Staphylococcus aureus (Zhang, Shen, Bao, He, Feng, & Zheng, 2008a; Zhang, Shen,

67

Weng, Zhao, Feng, & Zheng, 2009). In this sense, microemulsion could be an

68

approach to attain a balance between antimicrobial efficiency and odor acceptability

69

of EOs. However, up to now very little research has been carried out to formulate EO

70

microemulsions for antifungal purposes.

M AN U

SC

RI PT

61

In systematic preliminary investigations conducted in our laboratory, we tested

72

the antimicrobial activity of various EOs. From those, cinnamon and clove EOs were

73

screened as being effective. Moreover, a cinnamon EO microemulsion previously

74

established in our group controlled postharvest gray mold of pears without adverse

75

influence on fruit qualities (Wang, Zhao, Yu, Zhang, He, & Yao, 2014), indicating that

76

such technologies are very promising to satisfy consumer demand for commercial

77

formulations of EOs. Consequently, the present work aimed to (i) develop clove oil

78

microemulsions; (ii) determine their in vitro inhibitory activity against P. digitatum;

79

(iii) evaluate their capacity to control green mold in navel oranges by direct contact

80

and vapor phase.

81

2. Materials and methods

82

2.1 Materials

AC C

EP

TE D

71

4

ACCEPTED MANUSCRIPT Ethanol of analytical grade was procured from Shanghai Zhenxing Chemcial

84

No.1 Factory (Shanghai, China). Analytical grade Tween 80 was supplied by

85

Shanghai Shenyu Pharmaceutical & Chemical Co., Ltd. (Shanghai, China). These

86

chemicals were utilized without further purification. Commercially available clove

87

essential oil (CEO) from Syzygium aromaticum was purchased from Dongshi Essence

88

Perfume Co., Ltd. (Shanghai, China) and was stored at 4 °C in dark bottles prior to

89

use. According to the information given by the supplier, this oil was produced by

90

steam distillation method. Its major components were found to be eugenol (76.190%)

91

and β-caryophyllene (15.088%) (He et al., 2014).

92

2.2 Preparation of pathogen

M AN U

SC

RI PT

83

The navel orange fruit pathogen (P. digitatum), obtained from Institute of

94

Microbiology, Chinese Academy of Sciences (Beijing, China), was maintained on

95

potato dextrose agar (PDA) at 4 oC. P. digitatum was incubated for one week on PDA

96

at 28 oC prior to treatment. Spore suspensions were prepared by flooding and

97

suspending 1-week-old cultures of the pathogen in sterile distilled water (SDW).

98

Spore concentrations were determined by a haemocytometer and adjusted to

99

approximately 1.0×105 and 1.0×107 spores/ml with SDW.

101

EP

AC C

100

TE D

93

2.3 Formulation of CEO microemulsions CEO microemulsions were prepared as previously described (Wang, Zhao, Yu,

102

Zhang, He, & Yao, 2014). Two kinds of microemulsions were prepared: (1) ME-1: 1.0

103

g CEO, 2.0 g ethanol, 7.0 g Tween 80; and (2) ME-2: 1.0 g CEO, 3.0 g ethanol, 6.0 g

104

Tween 80. Briefly, CEO and ethanol were vigorously mixed at predetermined weight

5

ACCEPTED MANUSCRIPT ratios in glass test tubes sealed with removable caps at 25 oC. Tween 80 was then

106

added to the mixture under constant stirring using a magnetic stirrer (78-1B, Shanghai,

107

China) for 30 min. CEO microemulsions were stored at 4 oC and allowed to

108

equilibrate for at least 24 h at 25 oC before treatment to guarantee a steady-state

109

condition. In the two formulated microemulsions, evaporation loss was negligible.

110

After equilibration for a period of 24 h, the resulting microemulsions were diluted to

111

the instrument sensitivity range with deionized water to measure the mean particle

112

diameter using a Zetasizer Nano ZS (Malvern Instruments, UK) equipped with a

113

He-Ne laser (633.0 nm). The measurements were performed at a 90o scattering angle.

114

ME-1 and ME-2 showed a droplet size of 241.1 nm and 150.0 nm, respectively. The

115

stability of the developed microemulsions was then examined according to Zhang, Li,

116

Zhu, Feng, and Zheng (2011) with modifications. ME-1 and ME-2 were subjected to

117

centrifugation at 4000 g for 15 min and 1-month storage at 20 oC. It was observed that

118

no phase separation or creaming occurred.

119

2.4. In vitro antifungal effects of CEO microemulsions

EP

TE D

M AN U

SC

RI PT

105

MIC (Minimum inhibitory concentration) and MFC (minimum fungicidal

121

concentration) of CEO microemulsions were determined using 2-fold serial dilution

122

method (Jordán, Lax, Rota, Lorán, & Sotomayor, 2013) in order to assess their in

123

vitro antifungal activity. Aliquots (50 µl) of P. digitatum suspensions (approximately

124

1.0×107 spores/ml) were inoculated into 5 ml of potato dextrose broth (PDB)

125

containing suitable amounts of CEO microemulsions (0.0625-2 µl/ml). Both negative

126

(sterile PDB) and positive (5 ml of PDB + 50 µl of inoculum) controls were included.

AC C

120

6

ACCEPTED MANUSCRIPT 127

The samples were then incubated at 28 oC with shaking (200 rpm) for 48 h. The MIC

128

was recorded as the lowest concentration of microemulsions that completely inhibited

129

visible growth of P. digitatum. In order to determine MFC, 100 µl of each case without visible microbial growth

131

was plated on PDA. Plates were incubated at 28 oC for 48 h. The lowest concentration

132

at which P. digitatum failed to grow on PDA plates was defined as MFC. The MIC

133

and MFC of pure oil was also determined in a similar way. The assay was performed

134

in triplicate.

M AN U

SC

RI PT

130

The fungistatic and fungicidal effects of CEO microemulsions were considered

136

to be significantly (p < 0.05) enhanced when their MIC and MFC values were equal

137

to or higher than a twofold decrease compared with those of pure oil, respectively

138

(Monte et al., 2014).

139

2.5 The capacity of CEO microemulsions to control green mold in navel oranges

140

2.5.1 Direct addition assay

TE D

135

Navel oranges (Citrus sinensis L., Osbeck), harvested at commercial maturity,

142

were obtained from Gannan, China. Samples of uniform ripeness, size and free of

143

injuries were selected. The test fruits were surface-sterilized in sodium hypochlorite

144

(0.1%) for 60 s, scoured under running water and air dried at 25 oC. Fruits were gently

145

wounded (3 mm deep, 5 mm diameter) with a sterile puncher. A 30 µl aliquot of spore

146

suspension of P. digitatum (approximately 1.0×105 spores/ml) was pipetted into each

147

wound. Samples were then treated with 30 µl CEO microemulsions or pure oil at the

148

level of 0.25 µl/ml. SDW served as the control. After air drying for 1.5 h, the oranges

AC C

EP

141

7

ACCEPTED MANUSCRIPT were stored in enclosed plastic boxes to maintain a high relative humidity

150

(approximately 90%) at 25 oC. Disease incidence (infected wound number/total

151

wound number) and corresponding lesion diameter of oranges were examined after 5

152

days. Each treatment consisted of three replicates of 30 wounds each, and the

153

experiment was performed twice.

154

2.5.2 Vapor contact assay

RI PT

149

Vapor contact test was used to determine the antifungal effects of vapors of CEO

156

microemulsions as previously stated (Wang, Zhao, Yu, Zhang, He, & Yao, 2014).

157

Oranges were placed in 8-L plastic boxes after wounded and inoculated with the

158

pathogen as described above. For each box, a culture dish (3.5 cm diameter)

159

containing 30 µl SDW (control), pure oil (0.025 µl/ml) or CEO microemulsions

160

(0.025 µl/ml) was placed in the center. These boxes were then sealed using

161

polyethylene bags. Disease incidence (infected wound number/total wound number)

162

and corresponding lesion diameter of oranges were examined after 5 days’ storage at

163

25 oC. Each treatment consisted of three replicates of 30 wounds each, and the

164

experiment was performed twice.

165

2.6 Spore germination assay

M AN U

TE D

EP

AC C

166

SC

155

Pure oil and CEO microemulsions were added to 15-ml tubes containing 5 ml

167

PDB to achieve a final level of 0.25 µl/ml, respectively. SDW was added as the

168

control. Then a spore suspension (approximately 1×107 spores/ml) of 100µl was

169

inoculated into each tube. Spore germination (%) and germ tube length (µm) were

170

assessed following 18 h incubation at 28 oC/200 rpm. A spore was regarded as

8

ACCEPTED MANUSCRIPT germinated when the germ tube length equaled or exceeded that of the spore. At least

172

150 spores per replicate were microscopically examined for the presence of germ

173

tubes. The percentage of germinated spores was then estimated from the evaluated

174

spores. Furthermore, germ tube length (µm) was also determined. Each treatment

175

consisted of three replicates, and the experiment was performed twice.

176

2.7 Data analysis

RI PT

171

Statistical analyses were conducted with SAS version 8.2, via one-way ANOVA.

178

Duncan's test was then used to detect statistical significance. Differences in mean

179

values were considered significant when p < 0.05.

180

3. Results

181

3.1 In vitro antifungal activity of CEO microemulsions

M AN U

SC

177

The MIC and MFC values of CEO microemulsions in comparison to pure oil,

183

reported in Fig. 1, give a measurement of the antifungal activity. Microemulsification

184

of CEO caused a reduction of MIC from 0.50 µl/ml to 0.25 µl/ml, while the MFC

185

remained unchanged at 0.50 µl/ml. The lower MIC of CEO microemulsions suggested

186

their enhancement in antifungal activity relative to pure oil.

187

3.2 The capacity of CEO microemulsions to control green mold in navel oranges

188

3.2.1 Direct addition assay

EP

AC C

189

TE D

182

Direct addition assay was used to evaluate inhibitory effect of CEO

190

microemulsions on navel orange green mold. As shown in Fig. 2, pure oil and

191

microemulsions greatly delayed decay development. Moreover, the disease incidence

192

of navel oranges treated with microemulsion ME-1 and ME-2 was significantly (p <

9

ACCEPTED MANUSCRIPT 193

0.05) reduced by 34.51% and 20.93%, respectively, in comparison to the treatment

194

with pure oil.

195

3.2.2 Vapor contact assay Data shown in Fig. 3 indicated that pure oil and microemulsions in vapor phase

197

could also significantly (p < 0.05) inhibit P. digitatum on navel oranges after 5 days’

198

storage at 25 oC. CEO microemulsions exhibited the best control of lesion diameter

199

and decay development (57.34%-59.52%, 8.28-8.59 mm), followed by pure oil

200

(72.84%, 9.54 mm).

201

3.3 Spore germination assay

M AN U

SC

RI PT

196

Determination of spore germination and germ tube elongation could help to

203

explain the antifungal activity of CEO microemulsions. In the control group, all

204

spores germed and the germ tubes were too long and enwind each other (Fig. 4).

205

However, pure oil and microemulsions significantly (p < 0.05) inhibited fungal spore

206

germination rate and reduced germ tube length. The average suppressive efficacy was

207

in the following order: ME-1 ≈ ME-2 > pure oil > SDW control.

208

4. Discussion

EP

AC C

209

TE D

202

Although microemulsions have been utilized to dissolve hydrophobic

210

compounds for food, cosmetic, pharmaceutical and oil recovery applications (Ma &

211

Zhong, 2015), only a limited number of reports relevant to their use for antimicrobial

212

purposes are available. The utilization of microemulsions as antimicrobials is quite a

213

new and promising application. In the current work, we explored the possibility of

214

reinforcing CEO antimicrobial activity by loading it in microemulsion system.

10

ACCEPTED MANUSCRIPT 215

Interestingly, CEO microemulsions showed better control efficiency against P.

216

digitatum than pure oil in vitro and in vivo. In in vitro tests, CEO microemulsions exhibited enhanced fungistatic activity as

218

compared to pure oil. This phenomenon may result from the small droplet sizes of

219

CEO microemulsions (ME-1, 241.1 nm; ME-2, 150.0 nm), which could improve the

220

transport mechanisms through P. digitatum cell membrane (Donsìa, Annunziatab,

221

Sessaa, & Ferraria, 2011). Similarly, microemulsion was found to improve the

222

antimicrobial activity of glycerol monolaurate (the glycerol monoester of lauric acid)

223

(Fu, Feng, & Huang, 2006; Zhang, Shen, Bao, He, Feng, & Zheng, 2008a; Zhang, Lu,

224

Wang, Shen, Feng, & Zheng, 2008b). In the food additive industry, there are

225

increasing applications of using combinations of antimicrobial substances at

226

sub-lethal levels instead of putting reliance on individual food preservatives at high

227

concentrations (Roller, 1999). In this regard, enhanced fungistatic activity may imply

228

a promising application of CEO microemulsions.

TE D

M AN U

SC

RI PT

217

The functionality of antimicrobials needs to be checked in real food systems.

230

Hence, the in vivo antifungal activity of CEO microemulsions in the liquid and vapor

231

phases was determined subsequently. In agreement with a previous study, pure CEO

232

had some control effects on citrus green mold caused by P. digitatum (Shao, Cao, Xu,

233

Xie, Yu, & Wang, 2015). Additionally, better antifungal activity was found in CEO

234

microemulsions in the liquid phase. Similarly, cinnamon oil microemulsions

235

previously formulated in our laboratory exhibited higher in vivo antifungal activity

236

than pure ones (Wang, Zhao, Yu, Zhang, He, & Yao, 2014).

AC C

EP

229

11

ACCEPTED MANUSCRIPT The use of EO in vapor phase is an appealing approach to reduce its sensory

238

effect (Tyagi, Malik, Gottardi, & Guerzoni, 2012). The antimicrobial activity

239

generated by CEO vapor has been reported in previous literature. Tullio et al. (2007)

240

found that CEO vapor had a wide antifungal spectrum. Vapors of EO combinations of

241

clove and cinnamon exerted a synergism or antagonistic effect for the inhibition of

242

bacteria, depending on EO concentration applied (Goni, Lopez, Sanchez, Gomez-Lus,

243

Becerril, & Nerin, 2009). In the present paper, we evaluated the effect of vapors of

244

CEO microemulsions in controlling a major postharvest pathogen P. digitatum. Better

245

control activity was observed in microemulsified CEO. Moreover, CEO

246

microemulsions in the liquid and vapor phases exhibited quite similar antifungal

247

efficacy, evidencing that microemulsification technology may be a promising

248

approach to meet consumer demands for commercialization formulations of EOs.

TE D

M AN U

SC

RI PT

237

Exploring the mechanism of action could help to elucidate the remarkable

250

performance of CEO microemulsions. In this study, spore germination and germ tube

251

elongation of P. digitatum was significantly (p < 0.05) suppressed by pure oil and

252

microemulsions, which was indirect evidence of disruption and dysfunction of cell

253

walls and membranes. Furthermore, the greatest inhibition was observed in P.

254

digitatum treated with CEO microemulsions. Thus, it can be inferred that the

255

enhanced antifungal activity of CEO microemulsions might be due to the increase in

256

cell membrane permeabilization caused by the small droplet sizes of these

257

formulations.

258

AC C

EP

249

In conclusion, improved control activity of CEO against P. digitatum in vitro and

12

ACCEPTED MANUSCRIPT in navel oranges was achieved through microemulsification technology. Additionally,

260

CEO microemulsions exhibited stronger inhibitory activity on spore germination and

261

germ tube elongation than pure oil. Due to the enhanced antifungal activity of

262

microemulsified CEO in the vapor and liquid phases, lower antimicrobial

263

concentrations are required for utilization in food. This fact is of paramount

264

importance from a safety and organoleptic point of view. The sensory effect of CEO

265

might thus be reduced. These results suggest that CEO microemulsions established in

266

this work may be potential commercial formulations to control postharvest green

267

mold of navel oranges. Further investigations should be conducted to explore the

268

effects of these formulations on fruit quality traits, such as sensory acceptability,

269

weight loss, firmness, total soluble solids, ascorbic acid and color.

M AN U

SC

RI PT

259

Acknowledgment

TE D

270

This research was financially supported by Shanghai Municipal Education

272

Commission Science and Technology Innovation Foundation (12YZ165) and Science

273

and Technology Commission of Shanghai Municipality (13120503300).

AC C

274

EP

271

13

ACCEPTED MANUSCRIPT References

276

Burt, S. (2004). Essential oils: their antibacterial properties and potential applications

277

in foods – a review. International Journal of Food Microbiology, 94(3), 223–253.

278

Chen, Q., Xu, S., Wu, T., Guo, J., Sha, S., Zheng, X., et al. (2014). Effect of citronella

279

essential oil on the inhibition of postharvest Alternaria alternata in cherry tomato.

280

Journal of the Science of Food and Agriculture, 94(12), 2441–2447.

281

Davidson, P. M., Critzer, F. J., & Taylor, T. M. (2013). Naturally occurring

282

antimicrobials for minimally processed foods. Annual Reviews in Food Science and

283

Technology, 4, 163–190.

284

Donsìa, F., Annunziatab, M., Sessaa, M., & Ferraria, G. (2011). Nanoencapsulation of

285

essential oils to enhance their antimicrobial activity in foods. LWT - Food Science and

286

Technology, 44(9), 1908–1914.

287

Feng, W., & Zheng, X. (2007). Essential oils to control Alternaria alternata in vitro

288

and in vivo. Food Control, 18(9), 1126–1130.

289

Fu, X., Feng, F., & Huang, B. (2006). Physicochemical characterization and

290

evaluation of a microemulsion system for antimicrobial activity of glycerol

291

monolaurate. International Journal of Pharmaceutics, 321(1-2), 171–175.

292

Goni, P., Lopez, P., Sanchez, C., Gomez-Lus, R., Becerril, R., & Nerin, C. (2009).

293

Antimicrobial activity in the vapour phase of a combination of cinnamon and clove

294

essential oils. Food Chemistry, 116(4), 982–989.

295

He, S., Yang, Q., Ren, X., Zi, J., Lu, S., Wang, S., et al. (2014). Antimicrobial

296

efficiency of chitosan solutions and coatings incorporated with clove oil and/or

AC C

EP

TE D

M AN U

SC

RI PT

275

14

ACCEPTED MANUSCRIPT ethylenediaminetetraacetate. Journal of Food Safety, 34(4), 345–352.

298

Hulin, V., Mathot, A. G., Mafart, P., & Dufosse, L. (1998). Antimicrobial properties of

299

essential oils and flavour compounds. Sciences Des Aliments, 18(6), 563–582.

300

Jordán, M.J., Lax, V., Rota, M.C., Lorán, S., & Sotomayor, J.A. (2013). Effect of

301

bioclimatic area on the essential oil composition and antibacterial activity of

302

Rosmarinus officinalis L. Food Control, 30(2), 463–468.

303

Kellerman, M., Erasmus, A., Cronjé, P. J. R., & Fourie, P. H. (2014). Thiabendazole

304

residue loading in dip, drench and wax coating applications to control green mould

305

and chilling injury on citrus fruit. Postharvest Biology and Technology, 96, 78–87.

306

Ma, Q., & Zhong, Q. (2015). Incorporation of soybean oil improves the dilutability of

307

essential oil microemulsions. Food Research International, 71, 118–125.

308

Maqbool, M., Ali, A., Alderson, P. G., Mohamed, M. T. M., Siddiqui, Y., & Zahid, N.

309

(2011). Postharvest application of gum arabic and essential oils for controlling

310

anthracnose and quality of banana and papaya during cold storage. Postharvest

311

Biology and Technology, 62(1), 71–76.

312

Monte, D. F., Tavares, A. G., Albuquerque, A. R., Sampaio, F. C., Oliveira, T. C.,

313

Franco, O. L., et al. (2014). Tolerance response of multidrug-resistant Salmonella

314

enterica strains to habituation to Origanum vulgare L. essential oil. Frontiers in

315

Microbiology, 5, 721.

316

Roller, S. (1999). Physiology of food spoilage organisms. International Journal of

317

Food Microbiology, 50(1-2), 151–153.

AC C

EP

TE D

M AN U

SC

RI PT

297

15

ACCEPTED MANUSCRIPT Shao, X., Cao, B., Xu, F., Xie, S., Yu, D., & Wang, H. (2015). Effect of postharvest

319

application of chitosan combined with clove oil against citrus green mold. Postharvest

320

Biology and Technology, 99, 37–43.

321

Teixeira, P. C., Leite, G. M., Domingues, R. J., Silva, J., Gibbs, P. A., & Ferreira, J. P.

322

(2007). Antimicrobial effects of a microemulsion and a nanoemulsion on enteric and

323

other pathogens and biofilms. International Journal of Food Microbiology, 118(1),

324

15–19.

325

Tullio, V., Nostro, A., Mandras, N., Dugo, P., Banche, G., Cannatelli, M. A., et al.

326

(2007). Antifungal activity of essential oils against filamentous fungi determined by

327

broth microdilution and vapour contact methods. Journal of Applied Microbiology,

328

102(6), 1544–1550.

329

Tyagi, A. K., Malik, A., Gottardi, D., & Guerzoni, M. E. (2012). Essential oil vapour

330

and negative air ions: a novel tool for food preservation. Trends in Food Science &

331

Technology, 26(2), 99–113.

332

Wang, Y., Zhao, R., Yu, L., Zhang, Y., He, Y., & Yao, J. (2014). Evaluation of

333

cinnamon essential oil microemulsion and its vapor phase for controlling postharvest

334

gray mold of pears (pyrus pyrifolia). Journal of the Science of Food and Agriculture,

335

94(5), 1000–1004.

336

Xu, S., Yan, F., Ni, Z., Chen, Q., Zhang, H., & Zheng, X. (2014). In vitro and in vivo

337

control of Alternaria alternata in cherry tomato by essential oil from Laurus nobilis

338

of Chinese origin. Journal of the Science of Food and Agriculture, 94(7), 1403–1408.

339

Zeng, R., Zhang, A., Chen, J., & Fu, Y. (2012). Postharvest quality and physiological

AC C

EP

TE D

M AN U

SC

RI PT

318

16

ACCEPTED MANUSCRIPT responses of clove bud extract dip on ‘Newhall’ navel orange. Scientia Horticulturae,

341

138, 253–258.

342

Zhang, H., Shen, Y., Bao, Y., He, Y., Feng, F., & Zheng, X. (2008a). Characterization

343

and synergistic antimicrobial activities of food-grade dilution-stable microemulsions

344

against Bacillus subtilis. Food Research International, 41(5), 495–499.

345

Zhang, H., Lu, Z., Wang, S., Shen, Y., Feng, F., & Zheng, X. (2008b). Development

346

and antifungal evaluation of a food-grade U-type microemulsion. Journal of Applied

347

Microbiology, 105(4), 993–1001.

348

Zhang, H., Shen, Y., Weng, P., Zhao, G., Feng, F., & Zheng, X. (2009). Antimicrobial

349

activity of a food-grade fully dilutable microemulsion against Escherichia coli and

350

Staphylococcus aureus. International Journal of Food Microbiology, 135(3),

351

211–215.

352

Zhang, H., Li, D., Zhu, S., Feng, F., & Zheng, X. (2011). Antibacterial activities of a

353

food-grade dilution-stable microemulsion. Journal of Food Safety, 31(2), 232–237.

SC

M AN U

TE D

EP AC C

354

RI PT

340

17

ACCEPTED MANUSCRIPT Figure legends

356

Figure 1 Minimum inhibitory concentration (MIC) and minimum fungicidal

357

concentration (MFC) values of clove essential oil microemulsions against P.

358

digitatum.

359

Figure 2 The inhibitory effects of clove essential oil microemulsions on P.digitatum

360

decay development in artificially wounded and inoculated navel oranges. The disease

361

incidence (A) and lesion diameter (B) were measured after 5 days’ storage at 25 oC.

362

Vertical bars represent standard deviation. Different letters signify significant

363

differences (p < 0.05).

364

Figure 3 The inhibitory effects of vapors of clove essential oil microemulsions on

365

P.digitatum decay development in artificially wounded and inoculated navel oranges.

366

The disease incidence (A) and lesion diameter (B) were measured after 5 days’

367

storage at 25 oC. Vertical bars represent standard deviation. Different letters signify

368

significant differences (p < 0.05).

369

Figure 4 Effects of clove essential oil microemulsions on spore germination (A),

370

germ tube elongation (B) and microscope images (C) of P. digitatum. Data represent

371

mean ± standard deviation. Different lowercase letters within a column indicate

372

significant differences (p < 0.05). ND (not determined), the germ tube length could

373

not be determined because the germ tubes were too long and enwind each other.

374

Germination and germ tube length were determined microscopically (C) after 18 h

375

incubation at 28 oC in potato dextrose broth (for control, magnification=960×; for

376

other treatments, magnification=2560×).

AC C

EP

TE D

M AN U

SC

RI PT

355

377 18

ACCEPTED MANUSCRIPT 378 379

Figure 1 (A)

380

ME-2

384

RI PT

383

ME-1

Pure oi

385

0.00

0.25

(B)

386 ME-2

391

Pure oi

TE D

390

ME-1

EP

389

Formulations

387 388

0.00

393 394

0.25

MFC (µl/ml)

AC C

392

0.50

M AN U

MIC (µl/ml)

SC

382

Formulations

381

19

0.50

ACCEPTED MANUSCRIPT 395 396

Figure 2 (A) 100

a

397

399 400

b 60

40

c c

401 402

0

403

(B) a

8

4

408 0

EP

410

Control

Pure oil

Treatments

AC C

409

ME-2

b

TE D

407

Lesion diameter (mm)

404

406

ME-1

Treatments

12

405

Pure oil

M AN U

Control

SC

20

RI PT

398

Infected fruits (%)

80

20

c c

ME-1

ME-2

ACCEPTED MANUSCRIPT 411

Figure 3

412 (A)

414

80

415 416

a

b c

60

c

40

0 Control

418 (B)

a 16

12

b

8

423

4

424

0

TE D

422

Lesion diameter (mm)

420 421

ME-1

Treatments

Control

Pure oil

AC C

426

EP

Treatments

425

ME-2

M AN U

419

Pure oil

SC

20

417

RI PT

100

Infected fruits (%)

413

21

b

b

ME-1

ME-2

ACCEPTED MANUSCRIPT 427 (A)

Figure 4

(C) 100

(B)

Control a

100

Pure oil a 80

60

b 40

c

c

60

40

ME-1 Control

ME-2 Pure oil

ME-1

ME-2

TE D EP AC C

428

22

b

ND

0

Control

M AN U

Treatments

SC

20

20

0

b

RI PT

Germ tube length (µm)

Spore germination (%)

80

Pure oil

ME-1

Treatments

ME-2

ACCEPTED MANUSCRIPT Highlights Two clove essential oil (CEO) microemulsions were formulated.




Microemulsions showed enhanced fungistatic activity against P. digitatum.




Microemulsion and its vapor controlled postharvest green mould of navel

RI PT




oranges.

Microemulsions decreased spore germination and germ tube elongation of P.

EP

TE D

M AN U

SC

digitatum.

AC C