Abstract
Bu çalışmada elma suyunun berraklaştırılması sırasında
fındık kabuğu hidrolizatı kullanılarak Bacillus subtilis’ten üretilen
ham pektinaz enziminin etkinliği analiz edilmiştir. Açıklık-koyuluk, bulanıklık
ve berraklık açısından enzim yükü, sıcaklık ve süreyi optimize etmek için
istenebilirlik analizine dayalı cevap yüzey metodu kullanılmıştır. Elma suyu
berraklaştırması, farklı enzim miktarları (% 0.3-0.7), pH (4-7), sıcaklık
(30-50 oC) ve süre (2-6 saat) kullanarak gerçekleştirilmiştir. RSM
sonuçları, %0.3 (w/v) enzim miktarı, 45.8 oC ve 2 saat optimum
berraklaştırma koşullarında 70.40 açıklık-koyuluk, 49.44 bulanıklık ve %88.33
berraklık ile sonuçlanmıştır. RSM modellerinin geçerliliğini doğrulamak için, L
değeri, bulanıklık ve berraklığın RMSE değerleri sırasıyla 4.65, 5.28 ve 9.15
olarak hesaplanmıştır. Sonuç olarak, düşük enzim miktarı ve sürede elde edilen
maksimum berraklık enzimi meyve suyu endüstrisi için kullanılabilir yapmaktadır.
Keywords
Berraklaştırma ham bakteriyal pektinaz istenebilirlik optimizasyon metodu cevap yüzey metodu depektinizasyon
References
- 1. Sakhale, B.K., Pawar, V.N., Gaikwad, S.S. (2016). Studies on effect of enzymatic liquefaction on quality characteristics of Kesar mango pulp. Int Food Res J, 23(2): 860-865.2. Whitaker, J.R. (1984). Pectic substances, pectic enzymes and haze formation in fruit juices. Enzyme Microb Technol, 4: 341-349.3. Sandri, I.G., Fontana, R.C., Barfknecht, D.M., Silveira, M.M. (2011). Clarification of fruit juices by fungal pectinases. LWT-Food Sci Technol, 44 (10): 2217-2222.4. Sandri, I.G., Lorenzoni, C.M.T., Fontana, R.C., Silveira, M.M. (2013). Use of pectinases produced by a new strain of Aspergillus niger for the enzymatic treatment of apple and blueberry juice. LWT-Food Sci Technol, 51(2): 469-475.5. Lee, W.C., Yusof, S., Hamid, N.S.A., Baharin, B.S. (2006). Optimizing conditions for enzymatic clarification of banana juice using response surface methodology (RSM). J Food Eng, 73: 55-63.6. Rai, P., Majumdar, G.C., Dasgupta, S., De, S. (2004). Optimizing pectinase usage in pretreatment of mosambi juice for clarification by response surface methodology. J Food Eng, 64: 397-403.7. Sin, H.N., Yusof, S., Hamid, N.S.A., Rahman, R.A. (2006). Optimization of enzymatic clarification of sapodilla juice using response surface methodology. J Food Eng, 73: 313-319.8. Abdullah, A.G.L., Sulaiman, N.M., Aroua, M.K., Megat Mohd Noor, M.J. (2007). Response surface optimization of conditions for clarification of carambola fruit juice using a commercial enzyme. J Food Eng Essex, 81(1): 65-71.9. Chen, X., Xu, F., Qin, W., Ma, L., Zheng, Y. (2012). Optimization of enzymatic clarification of green asparagus juice using response surface methodology. J Food Sci, 77(6): 665-670.10. Pinelo, M., Zeuner, B., Meyer, A.S. (2010). Juice clarification by protease and pectinase treatments indicates new roles of pectin and protein in cherry juice turbidity. Food Bioprod Process, 88: 259-265.11. Alam, MdS., Ahuja, G., Gupta, K. (2014). Enzymatic clarification of carrot juice by using response surface methodology. Agric Eng Int: CIGR J, 16(3): 173-179.12. Swain, M.R., Ray, R.C. (2010). Production, Characterization and application of a thermostable exo-polygalacturonase by Bacillus subtilis CM5. Food Biotechnol, 24: 37-50.13. Joshi, V.K., Parmar, M., Rana, N. (2011). Purification and characterization of pectinase produced from apple pomace and evaluation of its efficacy in fruit juice extraction and clarification. Indian J Nat Prod Resour, 2(2): 189-197.14. Kumar, S., Sharma, H.K. (2015). Enzymatic degumming of pineapple (Ananas comosus) mill juice using crude and commercial enzymes. J Food Measur Char, 9(3): 414-425.15. Bhardwaj, V., Garg, N. (2014). Production, purification of pectinase from Bacillus sp. MBRL576 isolate and its application in extraction of juice. Int J Sci Res, 3(6): 648-652.16. Uzuner, S., Cekmecelioglu, D. (2015). Enhanced pectinase production by optimizing fermentation conditions of Bacillus subtilis growing on hazelnut shell hydrolyzate. J Mol Catal B: Enzym, 113: 62-67. 17. Uzuner, S., Cekmecelioglu, D. (2014). Hydrolysis of hazelnut shells as a carbon source for bioprocessing applications and fermentation. Int J Food Eng, 10(4): 799-808. 18. Spanos, G.A., Wrolstad, R.E., Heatherbell, D.A. (1990). Influence of processing and storage on the phenolic composition of apple juice. J Agric Food Chem, 38: 1572-1579.19. Kahle, K., Kraus, M., Richling, E. (2005). Polyphenol profiles of apple juices. Mol Nutr Food Res, 49: 797-806.20. Usaga, J., Worobo, R.W., Moraru, C.I., Padilla-Zakour, O.I. (2015). Time after apple pressing and insoluble solids influence the efficiency of the UV treatment of cloudy apple juice. LWT Food Sci Technol 62(1): 218-224. 21. Murthy, M.S.R.C., Swaminathan, T., Rakshit, S.K., Kosugi, Y. (2000). Statistical optimization of lipase catalyzed hydrolysis of methyloleate by response surface methodology. Bioprocess Eng, 22: 35-39.22. Zahangir, A.M., Suleyman, A.M., Rosmaziah, W. (2009). Statistical optimization of process conditions for cellulose production by liquid state bioconversion of domestic wastewater sludge. Bioresour Technol, 99: 4709-4716.23. Alvarez, S., Alvarez, R., Riera, F.A., Coca, J. (1998). Influence of depectinization on apple juice ultrafiltration. Colloids Surf A: Physicochem Eng Asp, 138: 377-382.24. Kilara, A. (1982). Enzymes and their uses in the processed apple industry: A review. Process Biochem, 23: 35–41.
Abstract
The present study analyzed the
efficiency of crude pectinase produced from Bacillus subtilis using
hazelnut shell hydrolysate during clarification of apple juice. Response
surface methodology (RSM) based desirability analysis was carried out to
optimize the enzyme load, temperature, and time with respect to lightness,
turbidity and clarity. The apple juice clarification was performed at different
enzyme loads (0.3-0.7%), pH (4-7), temperature (30-50 oC) and time
(2-6 h). The RSM results revealed optimum clarification conditions of 0.3%
(w/v) enzyme load, 45.8 oC temperature, and 2 h of time resulting in
70.40 lightness, 49.44 turbidity and 88.33% clarity. To confirm the validity of
RSM models, RMSE values of L value, turbidity and clarity were calculated as
4.65, 5.28 and 9.15, respectively. As a conclusion, maximum clarity at a low
enzyme load and time makes the enzyme useful for juice industry.
Keywords
Clarification crude bacterial pectinase desirability optimization methodology response surface methodology depectinization
References
- 1. Sakhale, B.K., Pawar, V.N., Gaikwad, S.S. (2016). Studies on effect of enzymatic liquefaction on quality characteristics of Kesar mango pulp. Int Food Res J, 23(2): 860-865.2. Whitaker, J.R. (1984). Pectic substances, pectic enzymes and haze formation in fruit juices. Enzyme Microb Technol, 4: 341-349.3. Sandri, I.G., Fontana, R.C., Barfknecht, D.M., Silveira, M.M. (2011). Clarification of fruit juices by fungal pectinases. LWT-Food Sci Technol, 44 (10): 2217-2222.4. Sandri, I.G., Lorenzoni, C.M.T., Fontana, R.C., Silveira, M.M. (2013). Use of pectinases produced by a new strain of Aspergillus niger for the enzymatic treatment of apple and blueberry juice. LWT-Food Sci Technol, 51(2): 469-475.5. Lee, W.C., Yusof, S., Hamid, N.S.A., Baharin, B.S. (2006). Optimizing conditions for enzymatic clarification of banana juice using response surface methodology (RSM). J Food Eng, 73: 55-63.6. Rai, P., Majumdar, G.C., Dasgupta, S., De, S. (2004). Optimizing pectinase usage in pretreatment of mosambi juice for clarification by response surface methodology. J Food Eng, 64: 397-403.7. Sin, H.N., Yusof, S., Hamid, N.S.A., Rahman, R.A. (2006). Optimization of enzymatic clarification of sapodilla juice using response surface methodology. J Food Eng, 73: 313-319.8. Abdullah, A.G.L., Sulaiman, N.M., Aroua, M.K., Megat Mohd Noor, M.J. (2007). Response surface optimization of conditions for clarification of carambola fruit juice using a commercial enzyme. J Food Eng Essex, 81(1): 65-71.9. Chen, X., Xu, F., Qin, W., Ma, L., Zheng, Y. (2012). Optimization of enzymatic clarification of green asparagus juice using response surface methodology. J Food Sci, 77(6): 665-670.10. Pinelo, M., Zeuner, B., Meyer, A.S. (2010). Juice clarification by protease and pectinase treatments indicates new roles of pectin and protein in cherry juice turbidity. Food Bioprod Process, 88: 259-265.11. Alam, MdS., Ahuja, G., Gupta, K. (2014). Enzymatic clarification of carrot juice by using response surface methodology. Agric Eng Int: CIGR J, 16(3): 173-179.12. Swain, M.R., Ray, R.C. (2010). Production, Characterization and application of a thermostable exo-polygalacturonase by Bacillus subtilis CM5. Food Biotechnol, 24: 37-50.13. Joshi, V.K., Parmar, M., Rana, N. (2011). Purification and characterization of pectinase produced from apple pomace and evaluation of its efficacy in fruit juice extraction and clarification. Indian J Nat Prod Resour, 2(2): 189-197.14. Kumar, S., Sharma, H.K. (2015). Enzymatic degumming of pineapple (Ananas comosus) mill juice using crude and commercial enzymes. J Food Measur Char, 9(3): 414-425.15. Bhardwaj, V., Garg, N. (2014). Production, purification of pectinase from Bacillus sp. MBRL576 isolate and its application in extraction of juice. Int J Sci Res, 3(6): 648-652.16. Uzuner, S., Cekmecelioglu, D. (2015). Enhanced pectinase production by optimizing fermentation conditions of Bacillus subtilis growing on hazelnut shell hydrolyzate. J Mol Catal B: Enzym, 113: 62-67. 17. Uzuner, S., Cekmecelioglu, D. (2014). Hydrolysis of hazelnut shells as a carbon source for bioprocessing applications and fermentation. Int J Food Eng, 10(4): 799-808. 18. Spanos, G.A., Wrolstad, R.E., Heatherbell, D.A. (1990). Influence of processing and storage on the phenolic composition of apple juice. J Agric Food Chem, 38: 1572-1579.19. Kahle, K., Kraus, M., Richling, E. (2005). Polyphenol profiles of apple juices. Mol Nutr Food Res, 49: 797-806.20. Usaga, J., Worobo, R.W., Moraru, C.I., Padilla-Zakour, O.I. (2015). Time after apple pressing and insoluble solids influence the efficiency of the UV treatment of cloudy apple juice. LWT Food Sci Technol 62(1): 218-224. 21. Murthy, M.S.R.C., Swaminathan, T., Rakshit, S.K., Kosugi, Y. (2000). Statistical optimization of lipase catalyzed hydrolysis of methyloleate by response surface methodology. Bioprocess Eng, 22: 35-39.22. Zahangir, A.M., Suleyman, A.M., Rosmaziah, W. (2009). Statistical optimization of process conditions for cellulose production by liquid state bioconversion of domestic wastewater sludge. Bioresour Technol, 99: 4709-4716.23. Alvarez, S., Alvarez, R., Riera, F.A., Coca, J. (1998). Influence of depectinization on apple juice ultrafiltration. Colloids Surf A: Physicochem Eng Asp, 138: 377-382.24. Kilara, A. (1982). Enzymes and their uses in the processed apple industry: A review. Process Biochem, 23: 35–41.
Details
| Primary Language | English |
|---|---|
| Other ID | GD18024 |
| Journal Section | Articles |
| Authors | |
| Publication Date | June 15, 2018 |
| Published in Issue | Year 2018 Volume: 43 Issue: 4 |
