PaPer Ital. J. Food Sci., vol. 27 - 2015 385 - Keywords: kiwi, kiwi puree powder, freeze drying, maltodextrin, vitamin C - Freeze Drying oF Kiwi (ActinidiA deliciosA) Puree anD the PowDer ProPerties gülşah ÇalişKan, KaDriye ergün* and s. nur Dirim Department of Food Engineering, Ege University, Bornova, 35100, Izmir, Turkey *Corresponding author: kadriye_ergun555@hotmail.com AbstrAct In this study, it was intended to investigate the production of freeze dried kiwi (Actinidia delici- osa) puree in the form of powder that can be used as a natural alternative to synthetic additives used in food products such as pudding, instant tea, and sauces for improving their flavour. In or- der to obtain the powder product, kiwi puree as plain and with maltodextrin (Dextrose Equivalence of 10-12, as 10 % by weight) addition were freeze dried. Drying behaviour of plain kiwi puree and kiwi puree with MD were explained by Logarithmic model (r2=0.994, rMsE=0.024, χ2=0.0008) and Wang and singh model (r2=0.999, rMsE=0.012, χ2=0.0002), respectively. the effective moisture diffusivity (D eff ) value was calculated as 7.3x10−10 m2/s and it was observed that it was not affect- ed by the addition of MD. the vitamin c content of fresh kiwi fruit was evaluated as 66.3 mg/100 g kiwi and there was a loss of 17.1% for plain and 19.8% for MD containing powders respective- ly after freeze drying. It was also observed that, the addition of maltodextrin decreased cohesive- ness, on the other hand, increased bulk and tapped densities, average time values for wettability and solubility, and glass transition temperature of the powder products. mailto:kadriye_ergun555%40hotmail.com?subject= 386 Ital. J. Food Sci., vol. 27 - 2015 IntroDuctIon Kiwi fruit contains high amounts of vitamins (vitamin c (100-400 mg vitamin c/100 g), A, b 2 , and E), minerals (calcium, iron, copper, phos- phorus, magnesium, and potassium), carote- noids (beta carotene, lutein, and xanthophyll), phenolic compounds (flavonoids and anthocya- nins) and antioxidant compounds (cAssAno et al., 2006). Kiwi fruit is being processed to ob- tain juice, frozen food, wine, jam, marmalade, and canned and dried slices. Drying might be a suitable technique to prolong the shelf life of kiwi, which is susceptible for microbial spoil- age and softening due to its high moisture con- tent. Fruit juices, purees and powders are be- ing marketed due to an increased demand for ready-to-eat foods. In addition, powder products, with a long-term ambient shelf life and micro- biological stability can reduce the transporta- tion, and storage costs as well (JInApong et al., 2008). thus, alternatives to conventional pro- cessing technologies are being explored to pro- duce better quality products. Due to high con- tent of vitamin c, it is essential to protect vita- min c during drying of kiwi (KAyA et al., 2010). Freeze drying is an important process for the protection of sensitive compounds such as vi- tamin c, phenolic compounds, biological activ- ity, appearance, color, texture, aroma, and nu- tritional values of foods which compensates its high operating costs for drying of foods (ZEA et al., 2013; WAng et al., 2006). In addition, FEr- nAnDEs et al. (2011) reported that for producing whole fruit powder, drying fruits at low temper- ature and reduced pressure with low amounts of carrier is apparently the best alternate. be- cause, there exist some difficulties for drying of food extracts, juices, and purees because of the stickiness problems resulted by low glass tran- sition temperatures of their components such as sugars and organic acids. In order to prevent problems in drying and obtaining powder prod- ucts with acceptable properties, the drying aids that have high t g is to be used. the use of dry- ing agents such as gum arabic, maltodextrin, whey protein, sucrose etc. improves the drying process, and leads to an effective drying (nA- DEEM et al., 2011). numerous studies were carried out with freeze drying of foods which contain sensitive com- pounds such as carrot (LIn et al., 1998), pump- kin (QuE et al., 2008), kiwi (Ergün, 2012) man- go (shoFIAn et al., 2011) pineapple (MArQuEs et al., 2011), papaya (shoFIAn et al., 2011; MArQuEs et al., 2011) and guava (WAng et al., 2006). several researchers studied on drying of kiwi fruits such as convective, microwave, vac- uum microwave, and freeze drying (KAyA et al., 2010; Ergün, 2012; DoyMAZ et al., 2009; KIrA- nouDIs et al., 1997) methods. Describing dehydration kinetics is important in the design and optimisation of drying process- es (sIMAL et al., 2005). thin layer drying models, generally means to dry as one layer of sample which provide uniform temperature assumption and suitable for lumped parameter models, are important in mathematical modelling of drying. Although, models depend on the process condi- tions, they are practical and provide sufficiently good results (ErbAy and IcIEr, 2009). the prop- erties of food powders such as bulk density, hy- groscopicity, degree of caking, dispersibility, wet- tability, solubility, particle size, and size distri- bution are useful for design, and control of pro- cessing, handling, storage operations, and prod- uct quality control. properties of powder prod- ucts are usually studied in two groups such as particle properties (particle size, shape, distribu- tion, density and morphological properties), and bulk properties (bulk density, wettability, solu- bility, porosity, cohesiveness, and flowability). In this study it was intended to investigate the production of freeze dried kiwi (Actinidia de- liciosa) puree in the form of powder that can be used as a natural alternative to synthetic addi- tive used in food products such as pudding, in- stant tea, and sauces for improving their flavour. Also, an alternative product with the advantages of high nutritional value, long durability, easi- ness for usage in dry mixture formulations, be- ing portable easily, and a healthier food additive for the consumers consumption will be obtained. In addition to the mentioned purposes: it was also aimed to determine the drying behaviour of kiwi puree (pure and with 10% MD) during freeze drying and the effect of maltodextrin ad- dition and the properties of the powder product. MAtErIAL AnD MEthoDs the fresh kiwi fruits were obtained from a local supermarket in Izmir, turkey. they were peeled and grounded into puree by using a home type blender (tefal smart, Mb450141, turkey). In or- der to obtain the puree with maltodextrin addi- tion, maltodextrin (MD) with Dextrose Equiva- lence (DE) value of 10-12 (As chemical Indus- try and commerce Limited company, turkey) was added directly to puree in suitable amounts (10% by weight). Freeze drying the freeze drying experiments were performed in a pilot scale freeze dryer (Armfield, Ft 33 Vac- uum Freeze Drier, England). prior to drying kiwi puree was frozen in a layer of 3 mm in the petri dishes at - 40ºc in an air blast freezer (Frigos- candia, helsinborg, sweden) for two hours, then freeze dried under vacuum (13.33 pa ab- solute pressure), at - 48ºc condenser tempera- ture. the temperature of the heating plate was set to 30ºc, which was constant during the dry- ing process. the powder was obtained by grind- Ital. J. Food Sci., vol. 27 - 2015 387 ing the dried material, obtained as pellets of di- ameter of petri size, in a blender (tefal smart, Mb450141, turkey), and powder was stored in glass jars in the dark at 20±1ºc until further tests were carried out. Physical and chemical analyses the moisture content of kiwi puree and freeze dried kiwi puree powders (Kpp) were determined according to AoAc (2000). For this process, each experiment for increasing time periods was car- ried out with new samples of equal mass, and moisture loss was determined gravimetrically by using a digital balance with 0.01 precision (ohaus Ar2140, usA). Moisture ratio was cal- culated according to equation (1). (1) Where the M t , M 0 and M e are the moisture con- tent at any time, initial, and equilibrium mois- ture content (kg water/ kg dry matter), respective- ly. Drying data was fitted to ten well-known thin layer drying models (Lewis, page, Modified page I, henderson and pabis, Logarithmic (Asymptot- ic), Midilli, Modified Midilli, two-term, two-term Exponential, and Wang and singh) (ErbAy and IcIEr, 2009). nonlinear regression analysis was used to evaluate the parameters of the selected model by using statistical software spss 16.0 (spss Inc., usA). the goodness of fit was deter- mined using the coefficient of determination (r2), root mean square error (rMsE), and the reduced chi-square (χ2) that can be described by the equa- tions given by ErbAy and IcIEr, 2009. Where Mr exp,i and Mr pre,i is the experimental, and predicted moisture ratio at observation i; n is number of the experimental data points, and n is number of constants in model. the effective moisture diffusivity (D eff ) of freeze dried kiwi slices were calculated by Fick’s diffu- sion model (Eq. 2). (2) Where t is the time (s), D eff is the effective dif- fusivity (m2/s) and L is the thickness of sam- ples (m). For long drying times, a limiting case of Eq. (3) is obtained, and expressed in a loga- rithmic form; (3) the effective diffusivity was calculated by plot- ting experimental moisture ratio in logarithmic form versus drying time. From Eq.(3), a plot of ln Mr versus drying time gives a straight line with a slope of: (4) Water activity was measured by using testo- Ag 400, germany, water activity measurement device. the ph values of kiwi puree and the pow- ders were measured using a ph meter (Inolab WtW ph 720, germany) directly and after dis- solving the powder in deionised water (1 g/1 g) respectively. the color values (L*, a*, and b* values) of fresh kiwi fruits, and the powders were measured with Minolta cr-400 colorimeter, Japan, calibrated with white standard plate three times and results as the average of three measurements were ex- pressed in accordance with the cIE Lab. system. the L* value, is a measure of lightness which ranges between 0 and 100. Increases in a* val- ue in positive, and negative scales correspond to increases in red or green color, respectively. the b* value represents color ranging from yel- low (+) to blue (-). the vitamin c content of fresh kiwi fruits was determined according to hIşIL (2007). Freeze dried powders were rehydrated to the initial moisture content prior to the analysis. the in- dication principle of vitamin c value is based on extraction with 10% oxalic acid afterwards adding of 2,6-dichlorophenolindophenol solu- tion. the absorbance was measured at 518 nm by a Varian cary 50 uV/Vis spectrophotometer. Glass transition temperature glass transition temperature of the powder samples was determined by a Differential scan- ning calorimeter (tA Instruments, Q10, usA) equipped with a thermal analysis station. An empty sealed aluminum pan was used as a ref- erence in each test. nitrogen gas at a flow rate of 50 ml/min was used as the purge gas to avoid water condensation around the samples. About ten milligrams of kiwi sample was sealed in alu- minum pans and cooled from room temperature to -40°c at 10°c/min for formation of glassy state in kiwi sample and equilibrated for 10 min. the heating rate was 10°c/min and the temper- ature range varied between -40 and 120°c, de- pending on sample moisture content. Dsc ther- mograms, presenting the heat flow (W/g) and temperature relationship were used to analyze the thermal transitions in samples during heat- ing and cooling. tA Instruments universal anal- ysis software was used to analyze the onset, mid and end points of the glass transition. the glass transition temperature (tg) was calculated as the average of the onset and end point values. Thermo gravimetric analysis thermo gravimetric Analysis (tgA) was car- ried out by perkin Elmer Diamond tg/DtA (canada) under nitrogen flow. the assay con- 388 Ital. J. Food Sci., vol. 27 - 2015 ditions were as follows: isotherm at 30 °c and heating from 30.00°c to 1000.00°c at 10.00°c/ min. Five milligrams of equilibrated samples was introduced into the apparatus and the measure- ments were plotted during the heating. Scanning electron microscope (SEM) the morphology of the powder samples, pre- pared by placing the powders on aluminium stubs using a double-sided adhesive tape and then coating with gold, were examined with a scanning electron microscope (sEM- phillips XL- 30s FEg, Eindhoven, netherlands) operating at 5kV accelerating voltage. Analysis of the powder properties For the determination of bulk density, the method explained by JInApong et al. (2008) was used. the average wettability and solubili- ty times of freeze dried kiwi puree powders were determined by using the method explained by gong et al. (2008) and gouLA and ADAMopou- Los (2008), respectively. Flowability and cohe- siveness values of the powders were evaluat- ed in terms of carr index (cI) and hausner ra- tio (hr), respectively. both cI and hr were cal- culated from the bulk (ρ bulk ), and tapped (ρ tapped ) densities of the powder as shown below Eqs. (5) and (6), respectively. (5) (6) Statistical analysis Data were analyzed by using statistical soft- ware spss 16.0 (spss Inc., usA). the data were subjected to analysis of variance (AnoVA), and Duncan’s multiple range test (α=0.05) to deter- mine the difference between means. the drying experiments were replicated twice and all the analyses were triplicated. rEsuLts AnD DIscussIon Results of physical and chemical analyses Kiwi is harvested through a long season. how- ever, due to its high moisture content, storage period and its direct use in food compositions are limited and this makes necessary the drying to obtain pure, minimally processed, decreased in volume and easy to use form of the kiwi. the results of the experimental study showed that, it was possible to dry the fresh kiwi puree un- der the freeze drying condition. In order to im- prove the drying process, to see the effect of maltodextrin addition and to obtain a more sta- ble powder, maltodextrin was used as a drying aid. the amount of MD to be used to prevent quality losses during drying and to obtain pow- der which has almost the same properties with fresh kiwi was determined by the preliminary tests. For this purpose, MD with amounts of 5, 10, 15, and 20% of the puree weight were add- ed to the fresh kiwi puree. the addition of MD as 5% of the puree weight was not suitable since there was no decrease in the drying time of kiwi puree. For the MD amounts being more than 10 %, the powders lost their quality character- istics such as specific color, vitamin c content etc. similar results were observed by QuEK et al. (2007). It was reported that after addition of the 10% MD watermelon powders lost their red- orange color. therefore, as a result of the prelim- inary tests, the concentration of MD in the pu- ree necessary for successful drying and powder production was determined as %10 of the puree weight. ZEA et al. (2013) reported that powder obtained by freeze drying of guava and pitaya pulp was found to be very hygroscopic and diffi- cult to compact. In order to minimize this prob- lem the researchers added 10% maltodextrin to guava and pitaya mash. the drying behaviour of the freeze drying pro- cess was determined from the mass loss in sam- ples of known initial moisture content. For the drying process, the total drying time was deter- mined to be nine and ten hours respectively for the samples of kiwi puree, and kiwi puree with maltodextrin until getting constant weight of the samples. similar results were obtained by MArQuEs and FrEIrE (2005) in their freeze drying study on pulps of tropical fruits as ten to thirteen hours. the average values of the experimental results of the analysis applied on fresh kiwi puree and freeze dried powders are given in table 1. the initial moisture content of kiwi puree was found to be as 81.19 % (wet basis, wb), and this result was consistent with KAyA et al. (2010) (81% wb). the final moisture content of kiwi powder is 9.55 % (wb) after removal of 88.24% of water. For the sample with MD, 94.31% of water was removed where the initial dry matter content of the sample was higher than the plain sample due to malto- dextrin addition and the amount of water to be removed at the same drying time decreased. the residual moisture in the powder decreased, and the moisture content of the sample with MD was found to be 56% lower than the plain sample, and this differences between samples was found to be statistically significant (p<0.05). the moisture ratio were calculated by us- ing the determined moisture content values and the data were fitted to ten thin layer dry- ing models (Lewis, page, Modified page I, hen- derson and pabis, Logarithmic, Midilli, Modified Midilli, two-term, two-term Exponential, and Wang and singh). the coefficient of correlation Ital. J. Food Sci., vol. 27 - 2015 389 table 1 - the physical and chemical properties of kiwi puree and freeze dried kiwi puree powders. Properties Fresh kiwi puree Freeze dried kiwi Kiwi puree The freeze dried kiwi puree powder with MD puree powder with MD Moisture content (% wb) 81.19 ±0.02b 9.55±0.64r 73.82±0.04a 4.20±0.05p Water Activity 0.98 ±0.01b 0.28±0.03r 0.96±0.01a 0.22±0.01p pH 3.16±0.01a 3.37±0.01p 3.38±0.01a 3.60±0.02r Color L* 47.37±0.35a 77.93±0.53p 48.84±0.34a 78.12±0.44p a* -0.67±0.24b 1.16±0.09r -0.74±0.08a -6.53±0.12 p b* 17.5±0.29a 21.77±0.17p 17.85±0.18a 22.08±0.11p Vitamin C (mg/100g, wb) 66.3±0.28b 54.97±0.13r 51.07±0.09a 40.95±0.51p a-b Different letters in the same row indicate significant difference between averages of puree and puree with MD at P<0.05. p-r Different letters in the same row indicate significant difference between averages of powder and powder with MD at P<0.05. (r2) was accepted one of the primary criterion for selecting the best model to define the freeze drying curves of kiwi puree powders. For freeze drying process of kiwi puree the highest r2 val- ue (0.994), and the lowest rMsE (0.02459), and χ2 (0.00083) values were obtained from loga- rithmic model (Fig. 1). however, for freeze dry- ing of kiwi puree with MD the best fit was ob- tained from Wang and singh model (r2=0.999, rMsE=0.012, χ2=0.0002) (Fig. 2). In the liter- ature, the convective drying characteristics of kiwi slices were explained with two term expo- nential (KAyA et al., 2010), page (cEyLAn et al., 2007; sIMAL et al., 2005), and henderson and pabis (DoyMAZ, 2009) models. the effective moisture diffusivity (D eff ) of freeze dried kiwi puree and pure with MD were evaluated as 7.3x10−10 m2/s. the difference be- tween calculated values was 0.002x10−10 m2/s and this was not considered to be effective. KAyA et al. (2010) reported that the effective moisture diffusivity values of kiwi slices which were dried under different drying conditions (air velocity, temperature, and relative humidity) varied be- tween 0.589 and 6.574 x10−10 m2/s. sIMAL et al. (2005) reported that the effective moisture diffusivity of hot air dried kiwi slices (30-90°c) ranged between 3.00 and 17.21 x10−10 m2/s. the D eff value of kiwi powder was found to be similar to the D eff value (7.13x 10−10 m2/s) of kiwi slices which were dried at 50 °c hot air temperature (sIMAL et al., 2005). the effective moisture diffusivity values in foods are in the range of 10−12 to 10−6 m2/s. Water activity is considered as one of the most important quality factors especially for long term storage and also it is related to mois- ture content, and responsible for biochemical reactions. the values of water activity under 0.6 is generally considered as microbiological- Fig. 1 - Experimental and computed moisture ratio values obtained by selected models for pure kiwi puree powder (r2≥0.993). 390 Ital. J. Food Sci., vol. 27 - 2015 ly stable (QuEK, 2007) and between 0.20, and 0.40 ensure the stability of the product against browning, and hydrolitical reactions, lipid oxi- dation, auto-oxidation, and enzymatic activity (AMrQuEs et al., 2007). the water activity val- ues of freeze dried kiwi puree powders (plain powder and powder with MD) were found to be as 0.287, and 0.225, respectively. In literature water activity values around 0.28 was also ex- pressed for freeze dried guava and pitaya pow- ders with 10% MD (ZEA et al., 2013). Drying process and addition of MD showed the signifi- cant effects on the water activity of freeze dried kiwi puree powders (p<0.05). the ph value of kiwi puree was measured as 3.16. souFLErosA et al. (2001) reported that the ph value of kiwi ranges between 3 and 4, due to the content of including the acids such as gluconic, galacturonic, oxalic, succinic, fumar - ic, oxcaloacetic, and p-coumaric acids. hArDEr et al. (2009) and ArroQuI et al. (2004) meas- ured the ph value of kiwi nectar and puree as 3.50 and 3.41, respectively. the ph values of powders (kiwi puree powder and powder with MD) were found to be as 3.37 and 3.60, respec- tively. results showed that the drying process and addition of MD caused a significant in- crease in the ph value of powders (p<0.05). the increase in the ph values was found as 6.65% and 6.51% for plain and MD containing pow- ders, respectively. this increase was compara- ble with the increase in 3.64% in freeze drying of guava concentrate MAhEnDrAn (2010) and the reason for the increase can be explained with the loss of some acidic compounds dur- ing drying. color of the dried products is an import- ant quality factor, which reflects the senso- ry attractiveness, and the quality of the pow- ders (QuEK et al., 2007). thus, the color of the processed products should ideally remain unchanged after production. the color values (L*, a* and b*) of kiwi puree were measured as 47.37, -0.67, and 17.5 respectively. these values are quite different than the measure- ments of Ancos (1999) reporting the color val- ues (L*, a*, and b*) of kiwi puree 36.01, -12.35 and 23.03, respectively and this shows the dif- ferences between the cultivars and the stor- age time after harvest. the variation of color values for plain and MD containing samples depending on the drying time were shown in Figs. 3 and 4, respectively. As shown in Fig. 3, the L*, b* and a* values of freeze dried kiwi puree powder increased throughout the drying period and reached the final values as 77.93, 1.16, and 21.77, respectively. chopDA and bArrEtt (2001) reported that the increase in L* (brightness), a* (redness) and b* (yellow- ness) values following production of guava pu- ree powder was most likely a result of non-en- zymatic browning during freeze drying which produced a darker product. the addition of MD in freeze drying, increased the L* (78.12), and b* (22.08) values, but decreased a* val- ue (-6.53) (table 1). results showed that, dry- ing process increased the brightness values of samples (p<0.05); addition of MD caused su- perior bright color but it was not found to be statistically significant (p>0.05). the same ef- fect was also observed for yellow-blue (b*) val- ue. nevertheless, both drying process, and ad- dition of MD showed a significant effect on the green-red (a*) value of the samples (p<0.05). For the determination of vitamin c, freeze dried powders were rehydrated to the initial moisture content prior to the analysis to obtain comparable results. the vitamin c content of kiwi was found Fig. 2 - Experimental and computed moisture ratio values obtained by selected models for kiwi puree powder with MD (r2≥0.994). Ital. J. Food Sci., vol. 27 - 2015 391 Fig. 3 - the variation of color values of plain samples depending on the drying time. to be as 66.3±0.28 mg/ 100 g (wb) kiwi. the freeze drying process caused a significant (17.1%) de- crease on the vitamin c content of kiwi powder (p<0.05). the vitamin c loss during drying is sim- ilar to losses of 18.8% (MAhEnDrAn, 2010) and 16% (MArQuEs et al. 2006) during freeze drying of some other fruit concentrate and pulps. Also, the addition of MD caused an insignificant loss in the vitamin c content (19.82%) (p>0.05). this decrease may occur due to the dilution effect. Exposure to heat, light, oxygen and metals may also lead to vitamin c losses. LIn et al. (1998) did not observed significant loss of Vitamin c in freeze-dried carrots. the vitamin c losses can be due to not only the freeze drying, but also by the operations before drying such as cutting, slicing and freezing. therefore, grinding process, prepa- Fig. 4 - the variation of the color values of samples with MD depending on the drying time. ration of maltodextrin and kiwi puree blend may cause more vitamin c losses for the kiwi puree. MArQuEs et al. (2011) reported that the vita- min c losses for freeze dried fruits are consider- ably smaller when compared the vitamin c loss- es caused to others drying methods due to the low temperatures, and to the use of vacuum in the process. Glass transition temperature In order to have safety storage, and stability of powders, the powders should be kept below glass transition temperature (t g ). so the t g val- ue of kiwi powders was determined. Kiwi pow- der exhibited well defined t g (average -18°c) rep- resented by an endothermic change in the base 392 Ital. J. Food Sci., vol. 27 - 2015 line (Fig. 5). Moisture content and water activi- ty are the main factors affecting t g of materials. however, in the consideration of food materials with similar moisture content and water activi- ty values, the high acid and sugar content may decrease the t g value. the increases in t g val- ues of kiwi puree powders with carriers possi- bly due to the addition of carriers, and the low- er moisture content of carrier-incorporated pow- ders. t g of kiwi puree powders with MD (t g aver- age -5°c) was found to be higher (Fig. 6). sILVA et al. (2006) reported that, addition of 30% MD (w/w, DE20) increased tg of freeze dried camu- Fig. 5 - Dsc thermogram for freeze dried kiwi puree powders. camu pulp from -58.8°c to -40.1°c for the mois- ture content values between 0.2 to 0.5 (g dry sol- id/ g sample). After this value, t g increased rap- idly with decreasing moisture content. In their study, MosQuErA et al. (2010) observed an in- crease in tg with the addition of MD and this increase was slightly more where MD with low DE was used. Thermo gravimetric analysis the results of the analysis of the samples of kiwi puree powders by tgA are shown in Fig. 6 - Dsc thermogram for freeze dried kiwi puree powders with MD. Ital. J. Food Sci., vol. 27 - 2015 393 the Figs. 7 and 8. these spectra determine the changes of weight in relation to change of tem- perature that the samples experiment when exposed to heating from room temperature to 1000°c. tgA spectra showed that the loss of matter began around 50°c for both samples but the kinetics of thermal decomposition is differ- Fig. 7 - the variation of the weight of freeze dried kiwi puree powder with respect to time. ent for them. At 100°c, the sample with 10% MD lost around 6.5% of its own weight, but the sample that was dried without MD lost around 8.5% of its own weight. their components were considerably stable until 150°c because the loss of matter is not significant. however, between 100 and 220°c, reactions such as Maillard’s Fig. 8 - the variation of the weight of freeze dried kiwi puree powder with MD with respect to time. 394 Ital. J. Food Sci., vol. 27 - 2015 reaction or the condensation between phenolic acids and proteins may occur. As of 150°c, the loss of matter is significant, and the phenome- na are exothermic for all samples. Scanning Electron Microscope (SEM) selected images from the sEM microstructure analysis of the freeze dried kiwi puree powders were shown in Fig. 9 (a and b). the microstruc- tures of freeze-dried kiwi powder had a skele- tal-like structure with void spaces previously oc- cupied by ice prior to freeze drying. this is be- cause the absence of liquid phase in the mate- rial during freeze drying process suppressed the transfer of liquid water to the surface and the ice was converted to vapor without passing the liquid state (KroKIDA and MArouLIs, 1997). Mi- crographs revealed that powder particles of all Fig. 9 - scanning electron micrographs of freeze dried plain (a) and MD containing (b) kiwi puree powder at 500x magnification. powders were irregular in shape. Irregular shape of powder particles may due to the fibrous and porous nature of the kiwi fruit powders since powder was prepared from whole fruits (ZEA et al., 2013). Powder properties the powder properties of freeze dried kiwi pu- ree powders are given in table 2. the tapped and bulk densities of freeze dried kiwi puree pow- der were found to be as 0.257 and 0.161 g/ml, and the addition of MD significantly increased the tapped and bulk densities of powder (0.416 and 0.316 g/ml) (p<0.05). MArQuEs et al. (2006) reported that, apparent density of the studied pulps has presented a linear relationship with moisture content where the apparent densities of fruit pulps decreased linearly with moisture table 2 - the powder properties of freeze dried kiwi puree powders. Powder Properties Freeze dried kiwi puree powder Freeze dried kiwi puree powder with MD Tapped Density (g/mL) 0.26±0.01a 0.42±0.02b Bulk Density (g/mL) 0.16±0.01a 0.32±0.01b Solubility (s) 26±3a 290 ±48b Wettability (s) 78.5±2a 186 ±0.71b Flowability (CI) 38±3b (Bad) 24.04±2.87a (Fair) Cohesiveness (HR) 1.60±0.08b (High) 1.32± 0.05a (Intermediate) a-bDifferent letters in the same row indicate significant difference between averages at P<0.05. Ital. J. Food Sci., vol. 27 - 2015 395 content (dry basis) during freeze drying and the real density increased. the researchers report- ed that the remaining solids after moisture re- moval have higher densities than water and the overall solid density tends to increase as mois- ture is removed. MAhEnDrAn (2010) dried the guava concentrate with different drying meth- ods (freeze drying, tunnel drying and spray dry- ing with the 30, 40, 50 and 60% concentrations of MD) and the bulk density of guava powders were measured as 0.63 g/mL; 0.69 g/mL and 0.61, 0.60, 0.57 and 0.54 g/mL, respectively. In this study, on the contrary of the results given by MAhEnDrAn (2010) the bulk density increased with the addition of the MD. Lower density of the dried product is recommended to increase its attractiveness for consumers (DurAncE and WAng, 2002). the average solubility time of the freeze dried kiwi puree powder was found to be as 26 sec- onds. the reason for the addition of MD was to improve the drying process and at the same time maltodextrin is highly soluble in the wa- ter to be used as a carrier. however, addition of maltodextrin caused a significant increase in the average solubility time of the powder (290s) (p<0.05). In a study by MAhEnDrAn (2010) gua- va concentrate was dried with spray, tunnel, and freeze driers and the freeze dried guava powder was found highly soluble (96%) com- pared with the other drying methods. the solu- bility of the powder is related with moisture con- tent, particle size, and chemical conversions in the material (gouLA and ADAMopouLos, 2008). Wettability is the ability of the powder particles to overcome the surface tension between them- selves, and water. Wettability depends on par- ticle size, density, porosity, surface tension, surface area, and surface activity of particle. besides the effects of physical properties, the chemical composition of the powders also in- fluences wettability depending on the content of fats, proteins, and carbohydrates on their surface (FAng et al., 2008). Also, gouLA and ADAMApouLos (2008) reported that the resid- ual moisture content of the powder affects the bulk density, wettability, flowability, and co- hesiveness. the residual moisture content of powders is significantly affected the operational conditions, and carrier concentrations. the av- erage wettability time of freeze dried kiwi pow- der was found to be as 78.5 seconds. Addition of MD caused a significant increase in the av- erage wettability time as 186s (p<0.05). Flow difficulties and caking are common prob- lems in industries producing food powders. the flowability and cohesiveness properties of kiwi powders in terms of carr Index and hausner ratio were evaluated. the classification of pow- der flowability based on carr index (cI) is very good (<15), good (15-20), fair (20-35), bad (35- 45), and very bad (>45). the powder cohesive- ness based on hausner ratio (hr) is classified as low (<1.2), intermediate (1.2-1.4), and high (>1.4) (JInApong et al., 2008). Kiwi powder with higher moisture content showed bad flowabili- ty (37.15±3.15) and high (1.59±0.08) cohesive- ness. however, addition of MD caused a signifi- cant decrease in cohesiveness (1.29), and signif- icant increase in flowability (22.36) behaviours of powder (p<0.05). the kiwi powder containing MD with low moisture content showed superior flow properties compared to kiwi powder. concLusIons the present work describes the possibility of producing kiwi puree powder by freeze dry- ing, and the changes in some physicochemical and powder properties of powders which were affected by drying process and addition of MD. the results showed that freeze drying can sat- isfactorily be applied for drying of kiwi puree to obtain powders that can be used as an ingredi- ent which have high vitamin c content for fla- voring and improving nutritional value purpos- es. the possible uses of this dried product as a food supplement with valuable constituents of kiwi fruits and storage test might be studied in future projects. rEFErEncEs Ancos b. 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