Comparison of different ultrasound assisted extraction techniques for pectin from tomato processing waste

Journal Pre-proofs Comparison of different ultrasound assisted extraction techniques for pectin from tomato processing waste Animesh Singh Sengar, Ashish Rawson, Manimekalai Muthiah, Suresh Kumar Kalakandan PII: DOI: Reference:

S1350-4177(19)30860-0 https://doi.org/10.1016/j.ultsonch.2019.104812 ULTSON 104812

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Ultrasonics Sonochemistry

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3 June 2019 24 September 2019 27 September 2019

Please cite this article as: A.S. Sengar, A. Rawson, M. Muthiah, S. Kumar Kalakandan, Comparison of different ultrasound assisted extraction techniques for pectin from tomato processing waste, Ultrasonics Sonochemistry (2019), doi: https://doi.org/10.1016/j.ultsonch.2019.104812

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Comparison of different ultrasound assisted extraction techniques for pectin from

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tomato processing waste Animesh Singh Sengar, Ashish Rawson*, Manimekalai Muthiah, Suresh Kumar Kalakandan Indian Institute of Food Processing Technology Thanjavur- 613 005, Tamil Nadu, India. Corresponding author: Dr Ashish Rawson, e-mail: [email protected], [email protected]

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Abstract

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Concept of waste to wealth is a hot topic with research ongoing globally to reduce carbon

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footprint. In an effort to follow up this cause present study focused on tomato industry waste

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specifically the peel of tomatoes for extraction of pectin. Pectin extraction was performed

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using five different extraction techniques (Ultrasound assisted extraction (UAE); microwave

9

assisted extraction (MAE); ohmic heating assisted extraction (OHAE); ultrasound assisted

10

microwave extraction (UAME) and ultrasound assisted ohmic heating extraction (UAOHE) at

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different power levels to study its extraction and degradation kinetics and in turn to optimize

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the extraction process. The extracted pectin yield ranged from 9.30% for OHAE to 25.42 %

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for MAE. Also, there was very less difference in the yield of MAE and UAME extracted

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pectin, but at the cost of major difference in degree of esterification 59.76±0.70 and

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73.33±1.76 %, respectively. In addition, all the pectin extracted under optimized conditions

16

was having acceptable purity, [Galacturonic acid (GalA) content ranged from 675.8±11.31 to

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913.3±20.50 g/kg of pectin]. FTIR analysis confirmed the presence of functional groups in

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the finger print region of identification for polysaccharide in all the extracted pectin.

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According to obtained results, UAME can be considered as better green extraction

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technology in terms of extraction yield as well as in quality of pectin compared to the other

21

treatments used. Therefore, results suggest that UAME can be used as an efficient pectin

22

extraction method from tomato processing waste.

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Keywords: Ultrasonication, Microwave, Ohmic heating, extraction, Pectin.

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1. Introduction

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Tomato (Solanum lycopersicum) is widely consumed crop in the world as raw and in

28

processed forms [1]. According to FAOSTAT (2017)[2], total world production of tomato

29

accounted to be 18,23,01,395 tonnes. Out of this significant volume is processed yearly to

30

create products like tomato juice, paste, puree, ketchup and sauce for human utilization,

31

generating huge amounts of wastes from the food processing sector. Products which remain

32

after pressing of tomato majorly includes 27% peel, 33% seed and furthermore, 40% part of

33

pomace [3]. Tomato waste are usually disposed and/or utilized for animal feed or as manure

34

[4]. The waste produced along these food processing industries are viewed as the rich well-

35

spring of functional components like pectin, lycopene, and essential oils and so forth.

36

Moreover, they are low-cost raw materials and hence been under research in current years. In

37

recent research, tomato byproducts were used as ingredients for newly developed extruded

38

product [5].

39

The primary plant cell of fruits and vegetables is made out of polysaccharide like pectin,

40

hemicellulose and cellulose. The word Pectin is derived from a Greek word "Pektikos" which

41

implies “Coagulant” and is one of the most interesting functional component due to its

42

solubility and polyanionic nature [6]. It is majorly found in the portion of primary cell wall,

43

middle lamella and also in secondary cell walls of plant. Conventionally, pectin is isolated

44

from various food waste produced in food processing industries including citrus peel (85%),

45

apple pomace (14%) and sugar beet (<1%) [7].

46

Pectin is a heteropolysaccharide which is mainly composed of polymer of -galacturonic

47

acid (GalA) (not less than 65% according to standards for food grade pectin defined under

48

EU guideline no. 231/2012) which is an isomer of D-glucuronic acid (D-GlcA). Pectin,

49

according to the International numbering system has been defined as a food additive (Code

50

no. 440) and has no recommended maximum level for addition (limited to use lowest

51

possible level to achieve the desired effect). In terms of the degree of methylation (DM), it

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can be very well defined into two categories with their applications as high methoxyl pectin

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(DM  50%) and low methoxyl pectin (DM < 50%) [8]. High-methoxyl pectin can form gel

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when heated in sugar solution having solution concentration higher than 55Brix and pH

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maintained lower than 3.5. Though, low-methoxyl pectin can also form gel in the of presence

56

calcium ions. Pectin with higher degree of methylation are favored for food products for

57

achieving the desired consistency and structure in jam, jellies, etc. Whereas, low-methoxyl

58

pectin are used as fat replacer in ice creams, heat reversible bakery glazing agent, emulsified

59

meat products, low calorie beverages and also in fruit preparation for yoghurt [9].

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Traditionally, pectin is isolated from citrus fruit peel with techniques utilizing

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acidified water which are not only time and energy consuming, but also give poor yield and

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lead to the destruction of pectin structure. Though, novel techniques like MAE, UAE, OHAE

63

and combination of these were used and has been demonstrated to give better extraction

64

yields to overcome the limitations of conventional extraction method. Ultrasonication has

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always proved to be a better method for extraction, modification and blanching, which

66

creates new opportunities to produce bioactive compounds [10-14].

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In addition, pectin isolation highlights the multiple stage physicochemical process which are

68

influenced by parameters, for example, temperature, pH, extraction time, solvent, solid/liquid

69

ratio and number of extractions. As the extraction of pectin at industrial scale majorly relies

70

upon citrus fruit peels and apple pomace, hence newer potential sources for pectin extraction

71

are continuously being explored. Yang et al. [15] isolated pectin from potato pulp, similarly

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various researchers [16-21] studied the pectin extraction from grapefruit. Likewise, de

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Oliveira et al. [22] and Liew et al. [23] utilized passion fruit for isolating pectin. Also Yang et

74

al. [24] investigated that, sisal waste can be utilized for the extraction of pectin by

75

combination of enzymatic and ultrasonic method.

76

Despite the fact that, pectin is present in the majority of plant cells, however, the source used

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for pectin extraction are mainly restricted to apple pomace and citrus fruit peel at commercial

78

scale. Owing to the fact that conventional extraction can lead to wastage of large amount of

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solvents, energy, time and generation of carbon footprints. There has been an increased

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demand as well as focus on green novel technologies for extraction of important metabolites.

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Hence, the objective of this research were to establish new source and enhanced extraction

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technique utilizing different novel technologies (UAE; MAE; OHAE; UAME and UAOHE)

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for pectin extraction and furthermore to consider the impact of these techniques on the yield

84

of pectin and on its characteristic properties.

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2. Materials and methods:

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2.1. Materials:

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Fresh tomato (Solanum lycopersicum) were procured from local market, Thanjavur, India.

88

These were steam blanched (100oC for 15 min) and peel were removed manually. Tomato

89

peels were dried at 60C up to constant moisture level and were milled using electronic

90

pulverizer (Pulverisette 14, FRITSCH, Germany) to maintain the particle size  600 microns

91

by passing it through mesh sieve. Subsequently, the tomato peel powder (TPP) was vacuum

92

packed to avert moisture absorption.

93

2.2. Extraction and purification:

94

Parameters for extraction were studied in the initial trials as well those referred from

95

literature [19, 25] and the best proven ones were used for further extraction of pectin. The

96

details of which is discussed below.

97

2.2.1. Sample preparation for extraction:

98

Dried TPP was conditioned with the distilled water with solid-to-liquid ratio of 1:50 g/mL (to

99

avoid initial saturation of solvent during extraction process). Further pH of this solution was

100

maintained to 1.5 using 0.5 N HCl (extracting agent). Temperature of the solution was

101

monitored throughout extraction process [19, 25]. Figure 1 shows process flow chart for all

102

the extraction methods.

103

2.2.2. Ultrasound assisted extraction (UAE):

104

Ultrasound was applied using horn-type probe system (Sonic CV334, 220 V, 50/60 Hz). The

105

system with specification: power output 750 W, 20 KHz and having probe tip diameter 19

106

mm, with 12 mm immersed in solvent. Sonication was conducted at constant temperature of

107

60C on three power inputs 450 W, 600 W and 750 W. Treatment time was increased with

108

constant interval from 2, 4, 6, 8, 10, 12, 14 and 16 min with pulsation of 50% (30 s ON: 30 s

109

OFF).

110

2.2.3. Microwave extraction:

111

System used for extraction was household microwave system (900 W/ 2450 MHz) which

112

allows it to work at three different power 540, 720 and 900 W. Sample treatment time for

113

extraction was chosen with equal break of interims (0.667 min ie. 40 s) starting from 0.667,

114

1.334, 2, 2.667, 3.334, 4, 4.667 and 5.334 min. And the temperature was continuously

115

monitored during the study.

116

2.2.4. Ohmic heating assisted extraction (OHAE):

117

The extraction process in ohmic heating was performed using cuboidal chamber (80  80 

118

30) mm3 made from acrylic sheet (5 mm thick). The stainless steel plates having thickness 1

119

mm and area 2291 mm2 were used as electrodes. To investigate the changes in yield with

120

increasing power level and treatment time, the extraction was performed at 40V, 50V and

121

60V for 1, 2, 3, 4, 5, 6, 7 and 8 min, respectively. And the temperature was continuously

122

monitored during the study.

123

2.2.5. Ultrasound assisted microwave extraction (UAME):

124

In this, the TPP was subjected to sonication as pretreatment without any pH change though,

125

the solid to liquid ratio was maintained as 1:50 g/ml similar to the previously studied work by

126

[25]. As pretreatment, sonication was carried out at power levels of 450, 600 and 750 W for

127

time durations of 2, 4, 6, 8, 10, 12, 14 and 16 min with pulsation of 50% (30 s ON: 30 s

128

OFF). Following this the pH of the sample was adjusted to 1.5 using 0.5 N HCl which was

129

subsequently subjected to microwave extraction for 4 min at power level 540 W, with

130

continuous monitoring of temperature.

131

2.2.6. Ultrasound assisted Ohmic heating extraction (UAOHE):

132

The sonication as pretreatment was performed as mentioned in the method (2.2.5.) followed

133

by ohmic heating for 5 min at 60 V. And the temperature was continuously monitored.

134

2.2.7. Purification of extracted pectin:

135

After extraction, pH of solution was adjusted to 3.5 using 0.5 N NaOH. Supernatant of the

136

solution was separated by centrifugation at 5000 rpm for 20 min (10C). To this clear

137

solution, three volumes of ethanol (96%) was added and kept undisturbed for 8-10h at room

138

temperature to precipitate the dissolved pectin. This was further separated by centrifugation

139

at 5000 rpm for 20 min (10C). The extracted pectin was purified by washing it three times

140

with ethanol (95%) and dried at 50oC up to constant weight [16]. This purified sample was

141

further used for characterization of pectin.

142

Pectin yield (%), was estimated as ratio of dried extracted pectin mass (Mp) obtained after

143

extraction to the initial mass of tomato peel powder (Mw) used for extraction [1].

144

𝑀𝑝

𝑃𝑒𝑐𝑡𝑖𝑛 𝑦𝑖𝑒𝑙𝑑 (%) = 𝑀 × 100 𝑤

(1)

145

2.3. Study of extraction kinetics:

146

Extraction of pectin from plant cell structure goes in two transformations during the process:

147

(i) conversion of in-soluble pectin (protopectin) as soluble pectin and subsequent diffusion of

148

this from plant cell to solvent (dissolution rate constant, K1), (ii) degradation of partially

149

dissolved pectin during the extraction process (degradation rate constant, K2) [19].

150

Maximum extractable pectin % (Y0) was obtained by analysis of extract obtained following

151

three repeated continuous extractions from the same sample. However, yields for all the

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extraction process were recorded and study of extraction kinetics was performed using

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MATLAB R2019a. First-order two step rate equation was fitted to understand the extraction

154

kinetics of pectin for all extraction techniques used [26].

155 𝑌𝑎

𝐾1

= (𝐾 ― 𝐾 ) × (exp ( ― 𝐾1𝑡) ― exp ( ― 𝐾2𝑡)) 𝑌0 2 1

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(2)

157 158

where,

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𝑌𝑎 = Yield of pectin (%)

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𝑌0 = Maximum extractable pectin (%)

161

K1 = Dissolution rate constant (min-1)

162

K2 = Degradation rate constant (min-1)

163

t = actual extraction time (min)

164 165 166

2.4. Methods for evaluation of qualitative parameters: 1) Estimation of degree of esterification:

167

Titrimetric method as described by [24], was used for the determination of degree of

168

esterification (DE) and results were compared for all the extracted pectin.

169

2) Galacturonic acid content analysis:

170

Determination of GalA content of the extracted pectin was done by the spectrophotometric

171

method [27]. Results were compared for all the extracted pectin.

172

3) Pectin color determination:

173

The color of all extracted pectin was measured with calibrated Hunter Color Lab colorimeter

174

(Model: Color Quest XE, USA). These were expressed as L (Lightness: 0 as black, 100 as

175

white), a (-a for greenness, +a for redness) and b (-b for blueness, +b for yellowness) values.

176

4) FT-IR spectrum:

177

Fourier transform infrared spectroscopy (FT-IR) was used for characterization of purified

178

pectin structure. IR spectra was collected using FT-IR spectrophotometer, PerkinElmer, USA

179

[Spectrum two]. Spectra was used for structural analysis of pectin and curves were produced

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at resolution of 4 cm-1 with 16 scans ranging from 400 to 4000 cm-1.

181

5) Scanning electron microscopy:

182

Morphological observations of the residue after extraction were obtained by Scanning

183

Electron Microscopy. Samples were mounted on SEM specimen stub along double-side tape

184

prior to coating. Microscopy was carried out with (Model: VEGA3 TESCAN, Czech

185

Republic) system at 10 kV accelerating voltage with 1.00 KX magnification.

186

6) Data analysis:

187

All experiments were done in three replicates and Minitab Express 2018 used for analysis of

188

variance.

189

3. Results and discussion:

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3.1. Extraction kinetics:

191

Extraction process are governed by mass transfer principles and isolation of pectin is a

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function of: (a) Extraction through direct interaction of cell matrix with the wave, leading to a

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release of target compound in the cool solvent; (b) Heating of a solvent to its boiling point,

194

leading to dissolution of the target compound [28]. For better understanding of extraction

195

process and to determine the effect of parameters, kinetics of extraction was performed using

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first order two step kinetic model. The two constants used to explain the extraction process

197

were, dissolution rate constant (K1) and degradation rate constant (K2) as given in equation 2.

198

However, the predicted extraction time was calculated using equation 3.

199

3.1.1 UAE:

200

For UAE, (Figure 2 (a)) a maximum yield of 15.21% was obtained at power of 600 W, time

201

8.61 min and temperature 60C. Furthermore, it was observed that, with prolonged extraction

202

time the yield decreased to 14.29% in 16 min for the same power. For extraction at 750 W,

203

the maximum yield attained was 11.75%, whereas at 450 W, the yield obtained was 13.00%

204

which suggests the inadequate power input for efficient extraction. This phenomenon of

205

lower yield at higher power can be explained by the fact that long exposer time and

206

increasing power input causes disintegration of dissolved pectin and creates simpler

207

monosaccharides [29]. Dissolution rate constant (K1) was observed to increase with power,

208

further it was observed that initial rate of increase was higher and found to be 1.1410-1 min-1

209

for 450 W and 1.6210-1 min-1 for 600 W. Though, on further increase in power to 750 W, a

210

low rate of increase in K1 (1.6410-1 min-1) was observed. Degradation rate constant (K2)

211

was also observed to be increasing, 0.79510-1, 0.79810-1 and 1.10710-1 min-1 with power

212

input 450, 600 and 750 W, respectively. This illustrates that higher energy treatment

213

conditions results in accelerated structural breakdown of dissolved pectin side chain. Also,

214

the decrease in extraction yield with increasing power was observed which may be due to

215

higher bubble volume concentration or probably due to formation of cavity bubbles around

216

the tip of probe which could screen and create reduction in the energy transmission into the

217

medium, this is also considered as saturation effect [19].

218

3.1.2 MAE:

219

MAE showed highest yield of 25.42% at 900 W, temperature 88.7C and time 3.34 min

220

among all the extraction process (Table 1). However, on further increase in extraction time

221

for 4, 4.67 and 5.34 min at same power, it caused decline in yield of pectin to 24.97, 24.63

222

and 24.51%, respectively (figure 2 (b)). In addition, maximum yield obtained during MAE at

223

720 and 540 W were 24.45 (88.1C, 4.0 min) and 20.83% (85.3C, 4.0 min), respectively.

224

Thus the efficient extraction time for MAE to achieve the maximum yield at power of 900 W

225

was about 3.34 min. The mechanism behind MAE was the absorption of microwave energy

226

by the system to initiate accelerated dissolution of pectin and on further increasing of

227

extraction time, it provokes the degradation of pectin due to its thermolabile nature. The

228

values for constant K1 and K2 were obtained from equation 2, to study the effect on yield

229

with increasing time and power these were obtained for 540 W, 720 W and 900 W which

230

were K1, 3.11110-1, 3.76510-1 and 5.17510-1 min-1; K2, 0.26510-1, 0.29110-1 and

231

0.312710-1 min-1, respectively. The increasing trend was obtained for dissolution and

232

degradation rate constant with elevating power. For both the constants K1 and K2, the

233

increase was gradual for power level 540 to 720 W, whereas at 900 W it increased

234

drastically; this phenomenon may be due to higher temperature accumulation at elevated

235

power. It must be underlined that, temperature in the system used for MAE increased with the

236

increase in power and it could not be controlled. As reported earlier, microwave causes

237

loosening of cell wall structure and causes cleaving of parenchymal cells [30]. Thus, skin

238

tissues are unfolded up by microwave radiation at a substantial rate which increases the

239

interaction between the solvent and the extracting material. It clearly illustrates that, higher

240

energy promotes the permeation of the pectin though the resultant temperature increase

241

causes degradation of pectin which is undesirable and unavoidable.

242

3.1.3 OHAE:

243

OHAE (Figure 2 (c)) exhibit maximum yield of 10.65% at 60 V after 5.0 min treatment time

244

and attaining temperature 81C. However, the maximum yield obtained at 40 V and 50 V

245

after about 7.0 min (50.2C) and 5.0 min (62.4C) of extraction were 9.30 and 9.60%,

246

respectively. This may be because of better cell permeabilization was attained at 60 V due to

247

higher electric field strength and raised temperature. The dissolution rate K1 were found to be

248

2.0410-1, 2.2410-1 and 2.3910-1 min-1 for 40 V, 50 V and 60 V, respectively. The result

249

shows gradual increase in dissolution rate (K1) with increasing power along, moreover it was

250

found to be directly proportional to extraction yield. During OHAE, degradation rate (K2)

251

increased from 1.4910-1, 1.81810-1 and 1.9410-1 min-1 for 40 V, 50 V and 60 V,

252

respectively. This may be due to gradual increase in the temperature and permeation with

253

treatment time at lower electric field, so that it eliminates the thermal degradation of

254

extracted pectin. It was reported in previous study that, permeation of intercellular material

255

through cell wall increases with increasing electric field strength and creates more effective

256

extraction even at lower temperature [31].

257

3.1.4 UAME:

258

In this case varying ultrasound (US) pretreatment was conducted, followed by microwave

259

treatment at selected power level of 540 W for 4 min. During extraction, maximum yield

260

following UAME was 18.00%

261

temperature was 85.1C (Figure 2 (d)). It was found to be less when compared to yield

262

obtained following MAE alone which was 20.83% at same power of 540 W. This could be

263

due to continuous diffusion of pectin from plant cell during US pretreatment, which further

264

led to hydrolysis of partially dissolved pectin, as it was freely available during microwave

265

heating.

266

However, pectin obtained following UAME with US pretreatment of 600 W for 10.0 min,

267

and 750 W for 8.0 min were 16.70 and 15.25% respectively, with the final temperature of the

268

samples at 87.7C and 86.3oC in the same order.

(US pretreatment: 450 W after 8.0 min), and final

269

Dissolution rate (K1) for UAME were found to be increasing with US pretreatment

270

power input (450 W, 600 W, 750 W) to 1.68710-1, 1.71710-1 and 1.73410-1 min-1.

271

Whereas, higher degradation rate (K2) was obtained for UAME (at US pretreatment of 450

272

W) compared to MAE alone which was 0.54410-1 min-1 and 0.265810-1 min-1,

273

respectively, at same microwave power of 540 W. This shows that, degradation in case of

274

UAME was more as increasing temperature with US pretreatment followed by microwave

275

treatment accelerates the hydrolysis of pectin. Though Bagherian, Ashtiani, Fouladitajar and

276

Mohtashamy [25] observed opposite phenomenon in which UAME proved to give better

277

extraction yield compared to MAE for pectin extraction from grapefruit.

278

3.1.5 UAOHE:

279

In this case varying US pretreatment was conducted, followed by Ohmic heating at selected

280

power level of 60 V for 5 min. The maximum yield of 14.60% was obtained following

281

UAOHE (US pretreatment at 450 W for 10.0 min; Figure 2 (e)). Whereas the temperature

282

increased to 68.9C following UAOHE treatment. Whereas, UAOHE extraction yield for US

283

pretreatment of 600 W, 8.0 min and 750 W, 6.0 min was 13.20% and 11.50%, respectively.

284

This decrease in the yield of pectin with increasing power input of ultrasound may be because

285

of increasing viscosity which can have diminishing ohmic heating effect or due to hydrolysis

286

of pectin with increasing temperature during ohmic heating. Moreover, higher yield was

287

obtained following UAOHE extraction 14.6% compared to OHAE 10.65% at 60 V. This may

288

be because ultrasound disintegrates the peel cuticle and create larger surface area for solute-

289

to-solvent interaction. US pretreatment followed by ohmic heating develops higher electric

290

field strength and increases the temperature which causes accelerated permeation of

291

intercellular materials.

292

The dissolution rate (K1) for UAOHE was 1.1510-1, 1.5610-1 and 1.5910-1 min-1,

293

which was directly proportional to the US pretreatment as it was gradually increased.

294

Whereas degradation rate (K2) were 1.02410-1, 1.0710-1 and 1.07710-1 min-1, which

295

shows an increase in degradation rate kinetics of pectin following UAOHE treatment with

296

increase in US pretreatment. Also decrease in extraction yield at US pretreatment power of

297

600 W and 750 W was observed compared to 450 W, this may be due to higher disintegration

298

of cell cuticle which causes increase in freely available pectin, which can degrade with

299

increasing power.

300

3.1.6 General discussion of extraction technologies

301

The above results illustrates that in UAE, cavitation produced during treatment can

302

directly rupture the cell wall structure and initiate the extraction [32]. Whereas in MAE and

303

OHAE, the solvent gets heated up to dissolve pectin, though the mode of heating varies,

304

which affects the extraction efficiency.

305

The results for all the extraction techniques showed increasing dissolution rate and

306

degradation rate constants with increasing power and temperature. One can notice major

307

difference in dissolution rate of MAE (540 W) and UAME (450 W-US) table 1, however, the

308

difference in their yield was not much. It’s because of longer extraction time in case of

309

UAME, as present research was focused on to study the effect of ultrasound pretreatment

310

over different extraction technologies. Yield in all the extraction process for particular power

311

level increased rapidly with initial increase in treatment time followed by gradual decline in

312

the extraction rate. This decline in extraction rate or increase in degradation rate was due to

313

thermal and high ultrasound intensity degradation of pectin, as observed in the previous

314

studies [19, 29, 33]. Furthermore, the extraction yield is dependent on the rate of dissolution

315

as well as rate of degradation which act opposite to each other in effective yield of extraction.

316

Higher dissolution rate may lead to high extraction yield; where as higher degradation rate

317

leads to lower yield, hence these two factors work simultaneously contrary to each other and

318

together determine the final yield.

319

Also results illustrates that, all the methods which were used for extraction gave the

320

maximum possible yield up to some extent of power level and on further power

321

input/increasing time, the yield was found to decrease. In case of MAE and OHAE this may

322

be because of increase in temperature and thermolabile nature of pectin, which causes

323

hydrolysis of dissolved pectin. Whereas for UAE, increasing power intensity (cavitation)

324

degraded the structure of pectin by rupturing the side chains and converting it into simpler

325

monosaccharides which are not precipitated with alcohol [29]. Lower viscosity and surface

326

tension could be the reason behind the initial increase in pectin extraction during UAE.

327

Similar results were also suggested in previous studies [19]. The results obtained during

328

study indicates that power, temperature and extraction time creates significant influence on

329

the kinetic of extraction.

330

3.2. Characterization of extracted pectin sample:

331

3.2.1 Degree of esterification (DE%):

332

All the extracted pectin from tomato peel waste belonged to high methoxyl pectin, as evident

333

by the degree of esterification (DE) which were higher than 50%, regardless to the method of

334

extraction (Table 2). DE for all the extracted pectin ranged from 59.76 - 76.00%, so these

335

could be used as gelling agent and for other food applications. Also, the lowest DE was

336

obtained for MAE extracted pectin (59.76 %), this may be because of harsh temperature

337

extraction, thus the pectin obtained following MAE would take longer time for gel setting.

338

Whereas UAME had a DE of 73.33 % which was much higher showing that the pectin

339

obtained has good gelling strength. Previous studies [25] reported higher DE values, thus the

340

reduction in DE for all the extracted pectin may be because extraction was performed at

341

lower pH (1.5). Since, the DE results depends up on the nature of extraction material and

342

conditions maintained during extraction. In previous study, Bagherian, Ashtiani, Fouladitajar

343

and Mohtashamy [25] reported the same trend of decrease in DE for MAE. They found

344

comparative decrease in DE was more in MAE to UAME, 79.35 and 82.61%, respectively,

345

for pectin extraction from grapefruit.

346

3.2.2 Galacturonic acid content (GalA):

347

As shown in Table 2, GalA content of all the extracted pectin was much higher than 650 g

348

GalA kg-1 Pectin, thus these polysaccharides extracted can be considered as pectin and can be

349

used as food additive. MAE and UAME extracted pectin were having higher and statistically

350

similar (p0.05) galacturonic acid content among the five-extraction methods used. This

351

indicated that MAE and UAME were able to separate pectin from tomato peel waste more

352

efficiently compared to all the other extraction processes and thus the galacturonic acid

353

content was highest [24]. Also, it supports the lowest yield obtained in case of OHAE since

354

the galacturonic acid content was least for the same. Similar trend of results were reported

355

for tomato extracted pectin in previous study [34].

356

3.2.3 Color of pectin:

357

Color would be important parameter for pectin as it plays major role for acceptance before

358

being used as food additives. Tomato extracted pectin color was predominantly due to the

359

lycopene (as its insoluble in water and ethanol) and other water-insoluble pigments (Table 2).

360

During the extraction process, disintegration of cell wall makes the water-soluble pigments

361

available to get dissolved in solvent. These pigment gets trapped in pectin during the

362

precipitation stage. The values of L*, a* and b* i.e., color measuring parameter indicates the

363

effect of extraction method on the color of the pectin. UAME extracted pectin was having the

364

highest lightness (L*) value and least lycopene color was observed this may be due to US

365

pretreatment which extracts the lycopene to the solvent and followed microwave heating

366

causes destruction of lycopene into fragments like acetone, glyoxal, laevulinic aldehyde and

367

methyl-heptenone [35]. Whereas, UAE and MAE extracted pectin was having higher values

368

for a* and b*, respectively. Compared to all the extraction methods studied the highest

369

lightness value was observed for UAME pectin and hence can be considered as better quality,

370

due to higher consumer acceptability (table 2).

371

3.2.4 Structural analysis:

372

FTIR spectra analysis of extracted pectin from tomato peel waste were done to endorse the

373

identity of extracted pectin and to show the effect of extraction method on structural

374

properties of pectin. It was observed that, spectra of all the extracted pectin exhibited similar

375

transmittance pattern in accordance with commercial pectin spectra (Figure 3). The spectra

376

wavelength range from 950 to 1200 cm-1 are predominantly known as finger print region of

377

carbohydrate as it identifies the presence of major functional groups of polysaccharides [36,

378

37]. The absorption bands observed from 1011 to 1220 cm-1 corresponds to C-O-C glycoside

379

ring bond stretching, O-H bending and stretching of C-O bond in COOH. One can see this

380

region is same for all the pectin, insignificant to method of extraction. The spectra obtained

381

from commercial pectin shows higher intensity peaks which may be due to higher

382

concentration, whereas all other extracted ones were having lower intensities. The region

383

from 890 to 1000 cm-1 represents the low and moderate intensity bands assigned to C-C

384

skeletal vibrations. Whereas, these were only present in commercial pectin and not in

385

extracted pectin. It could be due acidic pH maintained during all the extraction process. The

386

band from 625 to 640 cm-1 are related to lower frequency vibrations of pyranoid ring, i.e., C-

387

C deformation vibration of pectin ring skeletal [1]. Also, the UAE extracted pectin was

388

having the least variation intensity, compared to the pectin obtained from other extraction

389

method. It could be due to cleavage of bonds during the high intensity ultrasound treatment.

390

Thus, the data obtained from FTIR shows similar pattern to that of obtained from commercial

391

pectin and corresponds to presence of esterified form of pectin.

392

3.2.5 Scanning Electron Microscopic Imaging:

393

The images produced by Scanning Electron Microscopy (SEM) clearly shows the difference

394

between the mechanism of all the extraction treatments employed. Different morphological

395

changes in the raw material surface after extraction were seen. Figure 4. (A), (B) and (C)

396

images are of UAE, MAE and OHAE residues after extraction, respectively. These all showed

397

significantly different tissue morphology and surface modification. Ultrasound treated tomato

398

peel sample (A) was having porous and loosened structure (shown in 1 and 2) which may be

399

created due to rupture of cavitation bubble. Encircled portion 1 and 2 shows deep holes on

400

the surface which indicates the targeted force of microjet produced during rupture of bubble.

401

Whereas, microwave treated tomato peel sample showed uneven surface, could be due to

402

microwave targeted strikes during the treatment. The highlighted portion on (B) as 3 and 4,

403

illustrates the area of depression and hump creation during microwave treatment. Ohmic

404

heating treated sample was having the least effect compared to UAE and MAE, which clearly

405

explains the inefficient extraction of pectin from the sample. Encircled area in (C) 5 and 6,

406

the lines around the depression indicates the permeation of intercellular material during

407

extraction process. In both the combination treatments, (figure 4. (D) and (E)) the effect of

408

ultrasound as well as following extraction method are visible. The UAME created more

409

disintegrated structure as one can see in encircled portion of (D) 7 and 8, which could be due

410

to combined effect of UAE and MAE. Whereas, UAOHE residues (figure 4. (E)) seems to

411

have depressions (due to cavitation) on the surface (indicated as 9) and those lines (region 10)

412

around them may represent the permeation (due to electric field strength) of intercellular

413

matter. This could be explained as Ultrasound and microwave has more effect on the

414

microstructure and proved to give better yield than ohmic heated, so the resultant

415

combination effect of both caused more disintegration.

416

4. Conclusion:

417

This work was done to create a new approach towards the valorization of tomato processing

418

waste. Different eco-friendly extraction technologies were used and their kinetics of

419

extraction were studied. All the results illustrated that, lower energy ultrasound followed with

420

microwave extraction can give better results in terms of quantity as well as quality. And also,

421

pectin extracted from tomato peel can be used as food additive as it fulfills all the standard

422

requirements.

423 424

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425

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Measurement and Characterization, 11 (2017) 2119-2130.

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Agricultural Science Procedia, 2 (2014) 244-251.

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528

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529

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530 531

B

C

E

D

F

532 Tomato processing waste (TPP)  Drying of tomato peel at 50C up to constant weight

MAE

UAE

OHAE

UAOHE

UAME

 Centrifuged to separate supernatant  Three parts of ethanol (96%) was added and kept undisturbed for 8 h.  Precipitate was separated and washed three times with ethanol (95%).  Dried at 50C up to constant weight.

MAE

UAME

UAE

UAOHE

Figure 1: Process flow chart for all the extraction methods.

OHAE

533 534

Figure 2: Effect of different extraction method on the yield of pectin are plotted. (a) UAE, (b) MAE, (c) OHAE, (d) UAME and (e) UAOHE.

535

536 537 538

Figure 3: FTIR spectra of pectin obtained from different extraction methods.

A

B

1

3

2

4

C

D

7

5

8

6

E

F

10 9

Figure 4: SEM images of tomato peel residue (A) UAE (B) MAE (C) OHAE (D) UAME (E) UAOHE and (F) untreated TPP.

Table 1: Kinetic parameters for extraction of pectin from tomato peel using different extraction methods

Extraction method

Po wer leve l

Dissolu tion rate (K1) (10-1 min-1)

Degrada tion rate (K2) (10-1 min-1)

Extrac ted pectin (%)

Actu al extra ction time (min)

Tempera ture of extractio n (C)

R2

RMS E

UAE

45 0 W 60 0 W 75 0 W

1.14

0.795

13.0 0

10.0 0

60.0

0. 95

0.03 08

1.62

0.796

15.2 1

8.00

60.0

0. 96

0.03 14

1.64

1.107

11.7 5

6.00

60.0

0. 93

0.03 20

1.68

0.544

18.0 0

8.00

85.1

0. 99

0.01 72

1.71

0.724

16.7 0

10.0 0

87.7

0. 94

0.03 97

1.73

0.828

15.2 5

8.00

86.3

0. 94

0.03 69

1.15

1.024

14.6 0

10.0 0

68.9

0. 91

0.03 39

UAM E*

UAOH E*

US (45 0 W) M W (54 0 W) US (60 0 W) M W (54 0 W) US (75 0 W) M W (54 0 W) US (45 0 W) O H (60

V) US (60 0 W) O H (60 V) US (75 0 W) O H (60 V)

1.56

1.070

13.2 0

8.00

72.1

0. 87

0.05 36

1.59

1.077

11.5 0

6.00

77.3

0. 92

0.04 17

Other Technologies

MAE

OHAE

54 0 W 72 0 W 90 0 W 40 V 50 V 60 V

3.11

0.265

20.8 3

4.00

85.3

0. 99

0.02 63

3.76

0.291

24.4 5

4.00

88.1

0. 97

0.04 48

5.17

0.312

25.4 2

3.34

88.7

0. 98

0.03 90

2.04

1.498

9.30

7.00

50.2

2.24

1.818

9.60

5.00

62.4

2.39

1.943

10.6 5

5.00

81.0

0. 91 0. 91 0. 92

0.03 07 0.03 02 0.02 71

* Extraction temperature mentioned in these methods are of followed microwave and ohmic heating technique.

Table 2: GalA content, DE% and color of extracted pectin for all the extracted pectin. Extraction method

Extraction conditions Pow er

UAE

600 W

MAE

900 W

OHAE

60 V

Time (t) (min) 8.00

GalA1

DE2

Color L*

a*

b*

825.0±22. 63b

66.43±1. 45c

54.92±0. 36c

13.49±0. 04a

24.22±0. 56a

3.34

911.7±18. 24a

59.76±0. 70d

50.96±0. 49d

11.07±0. 22c

24.9±0.6 6a

5.00

675.8±11. 31d

74.33±0. 74b

58.65±0. 35b

5.49±0.1 6e

19.87±0. 18c

US US 913.3±20. 73.33±1. 67.22±0. (450 (8.00 50a 76b 00a W) ) MW MW (540 (4.00 W) ) UAOHE US US 779.3±12. 76.00±0. 47.6±0.4 (450 (10.0 58c 88a 9e W) 0) OH OH (60 (5 V) min) 1 All the values are in g kg-1 of pectin. 2 Values are in percentage. Values are mean ± standard deviation (n=3). Values with different letters in same column differ significantly.

8.58±1.8 7d

21.72±0. 04b

12.69±0. 05b

23.28±0. 40a

UAME

Graphical Abstract

Highlights 1) Valorization of tomato processing waste using innovative technologies 2) UAME gave highest dissolution rate and lower degradation rate compared to UAOHE and UAE 3) UAME gave the best quality pectin with high DE % , GalA content and least colour. 4) Highest extraction yield of pectin was obtained with MAE