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Drying Technology
An International Journal
Volume 33, 2015 - Issue 13: Selected Papers from the 19th International Drying Symposium (IDS 2014), Part 1
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Original Articles

Recent Developments in High-Quality Drying with Energy-Saving Characteristic for Fresh Foods

Min ZhangState Key Laboratory of Food Science and Technology, Jiangnan University, Wuxi, Jiangsu, China;School of Food Science and Technology, Jiangnan University, Wuxi, Jiangsu, ChinaCorrespondence[email protected]
,
Huizhi ChenState Key Laboratory of Food Science and Technology, Jiangnan University, Wuxi, Jiangsu, China
,
Arun S. MujumdarState Key Laboratory of Food Science and Technology, Jiangnan University, Wuxi, Jiangsu, China;Department of Bioresource Engineering, Macdonald Campus, McGill University, Ste. Anne de Bellevue, Québec, Canada
,
Qifeng ZhongHaitong Food Group Company, Cixi, Zhejiang, China
&
Jincai SunHaitong Food Group Company, Cixi, Zhejiang, China
Pages 1590-1600 | Published online: 31 Aug 2015

REFERENCES

  • Huang, L.; Zhang, M. Trends in development of dried vegetable products as snacks. Drying Technology 2012, 30(5), 448–461.
  • Miranda, M.; Maureira, H.; Rodríguez, K.; Vega-Gálvez, A. Influence of temperature on the drying kinetics, physicochemical properties, and antioxidant capacity of aloe vera (Aloe barbadensis Miller) gel. Journal of Food Engineering 2009, 91(2), 297–304.
  • Mujumdar, A.S.; Law, C.L. Drying technology: Trends and applications in postharvest processing. Food and Bioprocess Technology 2010, 3(6), 843–852.
  • Wang, Y.; Zhang, M.; Mujumdar, A.S.; Mothibe, K.J.; Roknul, A.S.M. Study of drying uniformity in pulsed spouted microwave-vacuum drying of stem lettuce slices with regard to product quality. Drying Technology 2013, 31(1), 91–101.
  • Gaceu, L.; Lepadatescu, B. Gaceu, L.; Lepadatescu, B. Monitoring of the vegetables drying process using infrared images. Presented at the 2nd International Conference on Energy and Environment Technologies and Equipment and the 2nd International Conference on Agricultural Science, Biotechnology, Food and Animal Science, Brasov, Romania.
  • Wang, Y.; Zhang, M.; Mujumdar, A.S.; Mothibe, K.J. Microwave-assisted pulse-spouted bed freeze-drying of stem lettuce slices—Effect on product quality. Food and Bioprocess Technology 2012, 6(12), 3530–3543.
  • Costa, C.M.; Yang, S. Counting pollen grains using readily available, free image processing and analysis software. Annals of Botany 2009, 104(5), 1005–1010.
  • Nawirska, A.; Figiel, A.; Kucharska, A.Z.; Sokół-Łętowska, A.; Biesiada, A. Drying kinetics and quality parameters of pumpkin slices dehydrated using different methods. Journal of Food Engineering 2009, 94(1), 14–20.
  • De Beer, T.R.M.; Allesø, M.; Goethals, F.; Coppens, A.; Heyden, Y.V.; De Diego Lopez, H.; Rantanen, J.; Verpoort, F.; Vervaet, C.; Remon, J.P.; Baeyens, W.R.G. Implementation of a process analytical technology system in a freeze-drying process using Raman spectroscopy for in-line process monitoring. Analytical Chemistry 2007, 79, 7992–8003.
  • García-Martínez, E.; Igual, M.; Martín-Esparza, M.E.; Martínez-Navarrete, N. Assessment of the bioactive compounds, color, and mechanical properties of apricots as affected by drying treatment. Food and Bioprocess Technology 2013, 6(11), 3247–3255.
  • Ergünes, G.; Tarhan, S. Color retention of red peppers by chemical pretreatments during greenhouse and open sun drying. Journal of Food Engineering 2006, 76, 446–452.
  • Phungamngoen, C.; Chiewchan, N.; Devahastin, S. Effects of various pretreatments and drying methods on Salmonella resistance and physical properties of cabbage. Journal of Food Engineering 2013, 115, 237–244.
  • Jiang, H.; Zhang, M.; Liu, Y.; Mujumdar, A.S.; Liu, H. The energy consumption and color analysis of freeze/microwave freeze banana chips. Food and Bioproducts Processing 2013, 91(4), 464–472.
  • Contreras, C.; Martín-Esparza, M.E.; Martínez-Navarrete, N. Influence of drying methor on the rehydration properties of apricot and apple. Journal of Food Process Engineering 2012, 35(2), 178–190.
  • Doymaz, İ.; Kocayigit, F. Effect of pre-treatments on drying, rehydration, and color characteristics of red pepper (‘Charliston’ variety). Food Science and Biotechnology 2012, 21(4), 1013–1022.
  • Fang, Z.; Bhandari, B. Effect of spray drying and storage on the stability of bayberry polyphenols. Food Chemistry 2011, 129(3), 1139–1147.
  • Sagar, V.R.; Suresh, K.P. Recent advances in drying and dehydration of fruits and vegetables: a review. Journal of Food Science and Technology 2010, 47(1), 15–26.
  • Sablani, S.S. Drying of fruits and vegetables: Retention of nutritional/functional quality. Drying Technology 2006, 24(2), 123–135.
  • Li, Z.Y.; Wang, R.F.; Kudra, T. Uniformity issue in microwave drying. Drying Technology 2011, 29(6), 652–660.
  • Zhu, X.; Guo, W.; Wu, X.; Wang, S. Dielectric properties of chestnut flour relevant to drying with radio-frequency and microwave energy. Journal of Food Engineering 2012, 113(1), 143–150.
  • Jiang, H.; Zhang, M.; Mujumdar, A.S.; Lim, R. Analysis of temperature distribution and SEM Images of microwave freeze drying banana chips. Food and Bioprocess Technology 2012, 6(5), 1144–1152.
  • Wang, S.; Tang, J.; Johnson, J.A.; Mitcham, E.; Hansen, J.D.; Hallman, G.; Drake, S.R.; Wang, Y. Dielectric properties of fruits and insect pests as related to radio frequency and microwave treatments. Biosystems Engineering 2003, 85(2), 201–212.
  • Jiao, S.; Johnson, J.A.; Tang, J.; Tiwari, G.; Wang, S. Dielectric properties of cowpea weevil, black-eyed peas and mung beans with respect to the development of radio frequency heat treatments. Biosystems Engineering 2011, 108(3), 280–291.
  • Venkatesh, M.S.; Raghavan, G.S.V. An overview of microwave processing and dielectric properties of agri-food materials. Biosystems Engineering 2004, 88(1), 1–18.
  • Wang, Y.; Zhang, M.; Mujumdar, A.S. Effect of cassava starch gel, fish gel and mixed gels and thermal treatment on structure development and various quality parameters in microwave vacuum-dried gel slices. Food Hydrocolloids 2013, 33(1), 26–37.
  • Wang, R.; Zhang, M.; Mujumdar, A.S.; Jiang, H. Effect of salt and sucrose content on dielectric properties and microwave freeze drying behavior of re-structured potato slices. Journal of Food Engineering 2011, 106(4), 290–297.
  • Ogura, H.; Ishida, H.; Kage, H.; Mujumdar, A.S. Enhancement of energy efficiency of a chemical heat pump-assisted convective dryer. Drying Technology 2003, 21(2), 279–292.
  • Atuonwu, J.C.; van Straten, G.; van Deventer, H.C.; van Boxtel, A.J.B. Improving dryer energy efficiency and controllability simultaneously by process modification. Computers & Chemical Engineering 2013, 59, 138–144.
  • Tippayawong, N.; Tantakitti, C.; Thavornun, S. Energy efficiency improvements in longan drying practice. Energy 2008, 33(7), 1137–1143.
  • Atuonwu, J.C.; van Straten, G.; van Deventer, H.C.; van Boxtel, A.J.B. Improving adsorption dryer energy efficiency by simultaneous optimization and heat integration. Drying Technology 2011, 29(12), 1459–1471.
  • Sivill, L.; Ahtila, P. Energy efficiency improvement of dryer section heat recovery systems in paper machines—A case study. Applied Thermal Engineering 2009, 29(17–18), 3663–3668.
  • Tippayawong, N.; Tantakitti, C.; Thavornun, S.; Peerawanitkul, V. Energy conservation in drying of peeled longan by forced convection and hot air recirculation. Biosystems Engineering 2009, 104(2), 199–204.
  • Precoppe, M.; Janjai, S.; Mahayothee, B.; Müller, J. Improved energy efficiency of farmers' cooperative litchi drying operation in Northern Thailand. International Journal of Food Science & Technology 2013, 4(18), 2376–2383.
  • Saxena, A.; Maity, T.; Raju, P.S.; Bawa, A.S. Degradation kinetics of colour and total carotenoids in jackfruit (Artocarpus heterophyllus) bulb slices during hot air drying. Food and Bioprocess Technology 2010, 5(2), 672–679.
  • Akpinar, E.K. Determination of suitable thin layer drying curve model for some vegetables and fruits. Journal of Food Engineering 2006, 73(1), 75–84.
  • Atuonwu, J.C.; van Straten, G.; van Deventer, H.C.; van Boxtel, A.J.B. Model-based energy efficiency optimization of a low-temperature adsorption dryer. Chemical Engineering & Technology 2011, 34(10), 1723–1732.
  • Atuonwu, J.C.; Jin, X.; van Straten, G.; Deventer Antonius, H.C.V.; van Boxtel, J.B. Reducing energy consumption in food drying: Opportunities in desiccant adsorption and other dehumidification strategies. Procedia Food Science 2011, 1, 1799–1805.
  • Pal, U.S.; Khan, M.K. Calculation steps for the design of different components of heat pump dryers under constant drying rate condition. Drying Technology 2008, 26(7), 864–872.
  • Huang, L.; Zhang, M.; Wang, L.; Mujumdar, A.S.; Sun, D. Influence of combination drying methods on composition, texture, aroma and microstructure of apple slices. LWT - Food Science and Technology 2012, 47(1), 183–188.
  • Maskan, M. Microwave/air and microwave finish drying of banana. Journal of food engineering 2000, 44, 71–78.
  • Köse, B.; Erentürk, S. Drying characteristics of mistletoe (Viscum album L.) in convective and UV combined convective type dryers. Industrial Crops and Products 2010, 32(3), 394–399.
  • Kraus, S.; Rother, M.; Steimle, P.; Gaukel, V.; Schuchmann, H.P.; Merk, D. Modular drying processor for application of combined drying processes. Chemie Ingenieur Technik 2011, 83(6), 888–892.
  • Wang, Z.; Sun, J.; Chen, F.; Liao, X.; Hu, X. Mathematical modelling on thin layer microwave drying of apple pomace with and without hot air pre-drying. Journal of Food Engineering 2007, 80(2), 536–544.
  • Varith, J.; Dijkanarukkul, P.; Achariyaviriya, A.; Achariyaviriya, S. Combined microwave-hot air drying of peeled longan. Journal of Food Engineering 2007, 81(2), 459–468.
  • Vishwanathan, K.H.; Hebbar, H.U.; Raghavarao, K.S.M.S. Hot air assisted infrared drying of vegetables and itsquality. Food Science and Technology Research 2010, 16(5), 381–388.
  • Schössler, K.; Jäger, H.; Knorr, D. Novel contact ultrasound system for the accelerated freeze-drying of vegetables. Innovative Food Science and Emerging Technologies 2012, 16, 113–120.
  • Xu, Y.; Zhang, M.; Mujumdar, A.S.; Zhou, L.; Sun, J. Studies on hot air and microwave vacuum drying of wild cabbage. Drying Technology 2004, 22(9), 2201–2209.
  • Li, F.; Li, L.; Sun, J.; Tatsumi, E. Effect of electrohydrodynamic (EHD) technique on drying process and appearance of okara cake. Journal of Food Engineering 2006, 77(2), 275–280.
  • Allen, P.H.G.; Karayiannist, G. Electrohydrodynamic enhancement of heat transfer and fluid flow. Heat Recovery Systems and CHP 1995, 15(5), 389–423.
  • Bai, Y.; Yang, Y.; Huang, Q. Combined electrohydrodynamic (EHD) and vacuum freeze drying of sea cucumber. Drying Technology 2012, 30(10), 1051–1055.
  • Hu, Q.; Zhang, M.; Mujumdar, A.S.; Du, W.; Sun, J. Effects of different drying methods on the quality changes of granular edamame. Drying Technology 2006, 24(8), 1025–1032.
  • Shih, C.; Pan, Z.; McHugh, T.; Wood, D.; Hirschberg, E. Sequential infrared radiation and freeze-drying method for producing crispy strawberries. Transactions of the ASABE 2008, 51(1), 205–216.
  • Pan, Z.; Shih, C.; McHugh, T.H.; Hirschberg, E. Study of banana dehydration using sequential infrared radiation heating and freeze-drying. LWT - Food Science and Technology 2008, 41, 1944–1951.
  • Xu, Y.; Zhang, M.; Mujumdar, A.S.; Duan, X.; Sun, J. A two-stage vacuum freeze and convective air drying method for strawberries. Drying Technology 2006, 24(8), 1019–1023.
  • Somjai, T.; Achariyaviriya, S.; Achariyaviriya, A.; Namsanguan, K. Strategy for longan drying in two-stage superheated steam and hot air. Journal of Food Engineering 2009, 95(2), 313–321.
  • Huang, L.; Zhang, M.; Mujumdar, A.S.; Sun, D.; Tan, G.; Tang, S. Studies on decreasing energy consumption for a freeze-drying process of apple slices. Drying Technology 2009, 27(9), 938–946.
  • Xu, Y.; Zhang, M.; Tu, D.; Sun, J.; Zhou, L.; Mujumdar, A.S. A two-stage convective air and vacuum freeze-drying technique for bamboo shoots. International Journal of Food Science and Technology 2005, 40(6), 589–595.
  • Roknul, A.S.M.; Zhang, M.; Mujumdar, A.S.; Wang, Y. A comparative study of four drying methods on drying time and quality characteristics of stem lettuce slices (Lactuca Sativa L.). Drying Technology 2014, 32(6), 657–666.
  • Pan, Z.; Khir, R.; Godfrey, L.D.; Lewis, R.; Thompson, J.F.; Salim, A. Feasibility of simultaneous rough rice drying and disinfestations by infrared radiation heating and rice milling quality. Journal of Food Engineering 2008, 84(3), 469–479.
  • Sandu, C. Infrared radiative drying in food engineering: A process analysis. Biotechnology Progress 1986, 2(3), 109–119.
  • Krishnamurthy, K.; Khurana, H.K.; Jun, S.; Irudayaraj, J.; Demirci, A. Infrared heating in food processing: An overview. Comprehensive Reviews in Food Science and Food Safety 2008, 7(1), 2–13.
  • Chen, H.; Zhang, M.; Fang, Z.; Wang, Y. Effects of different drying methods on the quality of squid cubes. Drying Technology 2013, 31(16), 1911–1918.
  • Lin, Y.; Tsen, J.; King, V.A.-E. Effects of far-infrared radiation on the freeze-drying of sweet potato. Journal of Food Engineering 2005, 68(2), 249–255.
  • Deng, Y.; Wu, J.; Su, S.; Liu, Z.; Ren, L.; Zhang, Y. Effect of far-infrared assisted heat pump drying on water status and moisture sorption isotherm of squid (Illex illecebrosus) fillets. Drying Technology 2011, 29(13), 1580–1586.
  • Deng, Y.; Liu, Y.; Qian, B.; Su, S.; Wu, J.; Song, X.; Yang, H. Impact of far-infrared radiation-assisted heat pump drying on chemical compositions and physical properties of squid (Illex illecebrosus) fillets. European Food Research and Technology 2011, 232(5), 761–768.
  • Deng, Y.; Qian, B.; Wu, J.; Su, S.; Feng, X. Characteristics of squid (Illex illecebrosus LeSueur) fillets dried using a combination of heat pump drying and far infrared radiation. Philippine Agricultural Scientist 2011, 94(3), 270–277.
  • Nathakaranakule, A.; Jaiboon, P.; Soponronnarit, S. Far-infrared radiation assisted drying of longan fruit. Journal of Food Engineering 2010, 100(4), 662–668.
  • Nimmol, C.; Devahastin, S.; Swasdisevi, T.; Soponronnarit, S. Drying and heat transfer behavior of banana undergoing combined low-pressure superheated steam and far-infrared radiation drying. Applied Thermal Engineering 2007, 27(14–15), 2483–2494.
  • Devahastin, S.; Suvarnakuta, P.; Soponronnarit, S.; Mujumdar, A.S. A comparative study of low-pressure superheated steam and vacuum drying of a heat-sensitive material. Drying Technology 2004, 22(8), 1845–1867.
  • Thomkapanich, O.; Suvarnakuta, P.; Devahastin, S. Study of intermittent low-pressure superheated steam and vacuum drying of a heat-sensitive material. Drying Technology 2007, 25(1), 205–223.
  • Nimmol, C.; Devahastin, S.; Swasdisevi, T.; Soponronnarit, S. Drying of banana slices using combined low-pressure superheated steam and far-infrared radiation. Journal of Food Engineering 2007, 81(3), 624–633.
  • Meeso, N.; Nathakaranakule, A.; Madhiyanon, T.; Soponronnarit, S. Modelling of far-infrared irradiation in paddy drying process. Journal of Food Engineering 2007, 78(4), 1248–1258.
  • Dondee, S.; Meeso, N.; Soponronnarit, S.; Siriamornpun, S. Reducing cracking and breakage of soybean grains under combined near-infrared radiation and fluidized-bed drying. Journal of Food Engineering 2011, 104(1), 6–13.
  • Karaaslan, S.N.; Tunçer, İ.K. Development of a drying model for combined microwave-fan-assisted convection drying of spinach. Biosystems Engineering 2008, 100(1), 44–52.
  • Zhang, M.; Tang, J.; Mujumdar, A.S.; Wang, S. Trends in microwave-related drying of fruits and vegetables. Trends in Food Science and Technology 2006, 17(10), 524–534.
  • Arikan, M.F.; Ayhan, Z.; Soysal, Y.; Esturk, O. Drying characteristics and quality parameters of microwave-dried grated carrots. Food and Bioprocess Technology 2011, 5(8), 3217–3229.
  • Geldart, D. Types of gas fluidization. Powder Technology 1973, 7(5), 285–292.
  • Feng, H.; Tang, J.; Cavalieri, R.P. Combined microwave and spouted bed drying of diced apples: Effect of drying conditions on drying kinetics and product temperature. Drying Technology 1999, 17(10), 1981–1998.
  • Feng, H.; Tang, J. Microwave finish drying of diced apples in a spouted bed. Journal of Food Science 1998, 63(4), 679–683.
  • Feng, H.; Tang, J.; Cavalieri, R.P.; Plumb, O.A. Heat and mass transport in microwave drying of porous materials in a spouted bed. AIChE Journal 2001, 47(7), 1499–1512.
  • Feng, H.; Tang, J.; Cavalieri, R.P. Dielectric properties of dehydrated apples as affected by moisture and temperature. Transactions of the ASABE 2002, 45(1), 129–135.
  • Yan, W.; Zhang, M.; Huang, L.; Tang, J.; Mujumdar, A.S.; Sun, J. Study of the optimisation of puffing characteristics of potato cubes by spouted bed drying enhanced with microwave. Journal of the Science of Food and Agriculture 2010, 90(8), 1300–1307.
  • Yan, W.; Zhang, M.; Huang, L.; Tang, J.; Mujumdar, A.S.; Sun, J. Studies on different combined microwave drying of carrot pieces. International Journal of Food Science and Technology 2010, 45(10), 2141–2148.
  • Yan, W.; Zhang, M.; Huang, L.; Tang, J.; Mujumdar, A.S. Influence of microwave drying method on the characteristics of the sweet potato dices. Journal of Food Processing and Preservation 2013, 35(5), 662–669.
  • Jumah, R.Y.; Raghavan, G.S.V. Analysis of heat and mass transfer during combined microwave convective spouted-bed drying. Drying Technology 2007, 19(3–4), 485–506.
  • Jindarat, W.; Sungsoontorn, S.; Rattanadecho, P. Analysis of energy consumption in a combined microwave–hot air spouted bed drying of biomaterial: Coffee beans. Experimental Heat Transfer 2014, 28(2), 107–124.
  • Duan, X.; Zhang, M.; Mujumdar, A.S.; Wang, S. Microwave freeze drying of sea cucumber (Stichopus japonicus). Journal of Food Engineering 2010, 96(4), 491–497.
  • Wang, Y.; Zhang, M.; Mujumdar, A.S.; Mothibe, K.J. Experimental investigation and mechanism analysis on microwave freeze drying of stem lettuce cubes in a circular conduit. Drying Technology 2012, 30(11–12), 1377–1386.
  • Jin, G.; Zhang, M.; Fang, Z.; Cui, Z.; Song, C. Numerical study on spout elevation of a gas-particle spout fluidized bed in microwave-vacuum dryer. Journal of Food Engineering 2014, 143, 8–16.
  • Lee, J.H.; Kim, H.J. Vacuum drying kinetics of Asian white radish (Raphanus sativus L.) slices. LWT - Food Science and Technology 2009, 42(1), 180–186.
  • Mothibe, K.J.; Wang, C.-Y.; Mujumdar, A.S.; Zhang, M. Microwave-assisted pulse-spouted vacuum drying of apple cubes. Drying Technology 2014, 32(15), 1762–1768.
  • Wang, J.; Luechapattanaporn, K.; Wang, Y.; Tang, J. Radio-frequency heating of heterogeneous food—Meat lasagna. Journal of Food Engineering 2012, 108(1), 183–193.
  • Luechapattanaporn, K.; Wang, Y.F.; Wang, J.; Tang, J.M.; Hallberg, L.M.; Dunne, C.P. Sterilization of scrambled eggs in military polymeric trays by radio frequency energy. Journal of Food Science 2005, 70(4), E288–E294.
  • Patel, K.K.; Kar, A. Heat pump assisted drying of agricultural produce-an overview. International Journal of Food Science and Technology 2012, 49(2), 142–160.
  • Alfaifi, B.; Tang, J.M.; Jiao, Y.; Wang, S.J.; Rasco, B.; Jiao, S.S.; Sablani, S. Radio frequency disinfestation treatments for dried fruit: Model development and validation. Journal of Food Engineering 2014, 120, 268–276.
  • Alfaifi, B.; Wang, S.J.; Tang, J.M.; Rasco, B.; Sablani, S.; Jiao, Y. Radio frequency disinfestation treatments for dried fruit: Dielectric properties. LWT - Food Science and Technology 2013, 50(2), 746–754.
  • Farag, K.W.; Lyng, J.G.; Morgan, D.J.; Cronin, D.A. A comparison of conventional and radio frequency thawing of beef meats: Effects on product temperature distribution. Food and Bioprocess Technology 2009, 4(7), 1128–1136.
  • Gao, M.; Tang, J.; Villa-Rojas, R.; Wang, Y.; Wang, S. Pasteurization process development for controlling Salmonella in in-shell almonds using radio frequency energy. Journal of Food Engineering 2011, 104(2), 299–306.
  • Jiao, S.; Tang, J.; Johnson, J.A.; Tiwari, G.; Wang, S. Determining radio frequency heating uniformity of mixed beans for disinfestation treatments. Transactions of the ASABE 2011, 54(5), 1847–1855.
  • Marra, F.; Zhang, L.; Lyng, J.G. Radio frequency treatment of foods: Review of recent advances. Journal of Food Engineering 2009, 91(4), 497–508.
  • Gong, Z.; Gao, L.; An, J.; Zhang, M.; Mujumdar, A.S.; Sun, J. Effects of predrying and vacuum impregnation with nano-calcium carbonate solution on strawberries, carrots, corn, and blueberries. Drying Technology 2009, 28(1), 36–41.
  • Mothibe, K.J.; Zhang, M.; Mujumdar, A.S.; Wang, Y.C.; Cheng, X. Effects of ultrasound and microwave pretreatments of apple before spouted bed drying on rate of dehydration and physical properties. Drying Technology 2014, 32(15), 1848–1856.
  • Wang, Y.; Zhang, M.; Adhikari, B.; Mujumdar, A.S.; Zhou, B. The application of ultrasound pretreatment and pulse-spouted bed microwave freeze drying to produce desalted duck egg white powders. Drying Technology 2013, 31(15), 1826–1836.
  • Li, Z.; Raghavan, G.S.V.; Wang, N. Apple volatiles monitoring and control in microwave drying. LWT - Food Science and Technology 2010, 43(4), 684–689.

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