Denizel Omurgasız Canlılardan Elde Edilen Kolajenler ve Kullanım Alanları

Erkan Uğurlu; Önder Duysak; Eyüp İlker Saygılı; Sinem Uğur; Selin Sayın

Review

Year 2020, Volume: 15 Issue: 1, 24 - 35, 31.01.2020

Erkan Uğurlu Önder Duysak Eyüp İlker Saygılı Sinem Uğur Selin Sayın

Abstract

References

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Denizel Omurgasız Canlılardan Elde Edilen Kolajenler ve Kullanım Alanları

Year 2020, Volume: 15 Issue: 1, 24 - 35, 31.01.2020

Erkan Uğurlu Önder Duysak Eyüp İlker Saygılı Sinem Uğur Selin Sayın

Abstract

Kolajen tüm canlılarda mevcut olan
bir protein molekülüdür. Kolajen kaynakları arasında su ürünlerinden elde
edilen kolajen, yüksek ürün eldesi, biyo-uyumluluk, yüksek işlenebilirlik ve herhangi
bir hastalık riski taşımaması gibi sahip olduğu avantajlı özelliklerinden
dolayı karasal kökenli kolajenlerin en iyi alternatifidir. Sadece balık ve
balık ürünlerinden ibaret olmayan denizel canlılardan omurgasızlar da iyi birer
kolajen kaynağıdırlar. Denizel omurgasızların medikal, tıp, biyomedikal,
farmakoloji, doku mühendisliği ve malzeme mühendisliği gibi birçok alanda ham
madde olarak kullanılması mümkündür. Bu derleme çalışmasında,
kolajen, kolajenin özellikleri, kolajenin yapısı ve tipleri ile ilgili
bilgilerin yanı sıra, denizel omurgasız canlılardan elde edilen kolajenler ve
bu kolajenlerin kullanım alanları hakkında son yıllarda yapılmış olan
çalışmalar derlenmiştir.

Keywords

Sucul Omurgasızlar, Doku Mühendisliği, Kolajen, Biyomateryal, Doku Mühendisliği

References

[1] Yang, H. and Shu, Z., (2014). The Extraction of Collagen Protein From Pig Skin. Journal of Chemical and Pharmaceutical Research, 6(2):683-687.
[2] Alberts, B., Bray, D., Lewıs, J., Raff, M., Roberts, K., and Watson, J.D., (1995). Molekularbiologie der Zelle. CH-Verlagsgesellschaft, Weinheim, 3. Auflage, Kap. 4, 7, 12.5, 16.5.6, 16.5.7, 19.3.8-22.7.
[3] Ferraro, V., Martinie, B.G., Sayd, T., Chambon, C., Anton, M., and Lhoutellier, V.S., (2017). Collagen Type I from Bovine Bone. Effect of Animal Age, Bone Anatomy and Drying Methodology on Extraction Yield, Self-Assembly, Thermal Behaviour And Electrokinetic Potential. International Journal of Biological Macromolecules.97:55–66.
[4] Song, H. and Li, B., (2017). Beneficial Effects of Collagen Hydrolysate: A Review on Recent Developments. Biomedical Journal of Scientific and Technical Research, 1(2):1-4.
[5] Lafarga, T. and Hayes, M., (2014). Bioactive Peptides from Meat Muscle and By-Products: Generation, Functionality and Application As Functional İngredients. Meat Science, 98(2):227-239.
[6] Schmidt, M.M., Dornelles, R.C.P., Mello, R.O., Kubota, E.H., Mazutti, M.A., Kempka, A.P., and Demiate, I.M., (2016). Collagen Extraction Process. International Food Research Journal, 23(3):913-922.
[7] Damodaran S., Parkin, K., and Fennema, O.R., (2010). Química de al imentos de fennema. p. 726-730. 4ª ed. São Paulo: Artmed.
[8] Cheng, F.Y., Hsu, F.W., Chang, H.S., Lin, L.C., and Sakata, R., (2009). Effect of Different Acids on the Extraction of Pepsin-Solubilised Collagen Containing Melanin From Silky Fowl Feet. Food Chemistry. 113(2):563-567.
[9] Ehrlich, H., Wysokowski, M., Żółtowska-Aksamitowska, S., Petrenko, I., and Jesionowski, T., (2018). Collagens of Poriferan Origin. Marine drugs.
[10] Li, P. and Wu, G., (2018). Roles of Dietary Glycine, Proline, and Hydroxyproline in Collagen Synthesis and Animal Growth. Amino Acids, 50(1):29-38.
[11] Szpak, P., (2011). Fish Bone Chemistry and Ultrastructure: Implications for Taphonomy and Stable İsotope Analysis. Journal of Archaeological Science. 38(12):3358–3372.
[12] Temel, B., (2006). Doğal ve Sentetik Biomateryallerde, Osteogenic (rhBMP-7) ve Angiogenic (bFGF) Büyüme Faktörleri İle İnsan Osteoblast Hücrelerinin Gelişiminin İncelenmesi. Yüksek Lisans Tezi. Çukurova Üniversitesi. s.54.
[13] Miller, A., (1984). Philosophical Transactions of the Royal Society. 11, 304. 4% -477.
[14] Khan, R., Khan, M.H., and Bey, A., (2011). Use of collagen as an Implantable Material in The Reconstructive Procedures, an overview. Biol Med. 3:25-32.
[15] Poole, A.R., Kobayashi, M., Yasuda, T., Laverty, S., Mwale, F., Kojima, T., Sakai, T., Wahl, C., El Maadawy, S., Webb, G., and Tchetina, E., (2002). Type II Collagen Degradation and Its Regulation in Articular Cartilage in Osteoarthritis. Annals of the rheumatic diseases, 61(suppl 2), 78-81.
[16] Gupta, R., Canerdy, T., Skaggs, P., Stocker, A., Zyrkowski, G., Burke, R., Wegford, K., Goad, J.T., Rohde, K., Barnett, D., DeWees, W., Bagchi, M., and Bagchi, D., (2009). Therapeutic Efficacy of Undenatured Type-II Collagen (UC-II) in Comparison to Glucosamine and Chondroitin in Arthritic Horses. Vet Pharmacol Ther. 32:577-584.
[17] Howkins, A., (2015). Elucidation of Porcine Corneal Ultrastructure to Inform Development of Corneal Xenografts or Biomimetic Replacements.
[18] Birmingham, J., Vilim, V., and Kraus, V., (2007). Collagen Biomarkers for Arthritis Application. Biomarkers insights. 1:61-76. PMCID: PMC2716783.
[19] Banu, N., Hotoshi, H., Shinukuro, K., and Genshi, E., (1994). A Novel Method for Concentrating Urinary Type IV collagen based on participation with polyethylene glycol: application to its measurement by enzyme immunoassay. Ann Clin Biochem.31:485-491.
[20] Lamandé, S.R. and Bateman, J.F.,(2018). Collagen VI Disorders: Insights on form and Function in the Extracellular Matrix and Beyond. Matrix Biology, 71, 348-367.
[21] Woodley, D., Keene, D., Atha, T., Huang, Y., Lipman, K., Li, W., Chen, M.,(2004). Injection of Recombinant Human Type VII Collagen Restores Collagen Function on Dystrophic Epidermolysis Bullosa. Nat Med.10:693-695.
[22] Gelse, K., Poschl, E., and Aigner, T., (2003). Collagens-Structure, Function, And Biosynthesis. Adv Drug Deliv Rev. 55:1531-1546.
[23] Wotton, S., Duance, V., and Fryer, P., (1988). Type IX Collagen: a Possible Function in Articular Cartilage. FEBS Lett. 234:79-82.
[24] Ricard-Blum, S., (2010). The Collagen Family. Cold Spring Harbor Perspectives in Biology. 3:a004978.
[25] Karsdal, M., (2016). Biochemistry of Collagens Structure, Function and Biomarkers. London, United Kingdom: Academic Press.
[26] Brinckmann, J.C.B.C., Notbohm, H., Muller, P.K., and Bachinger, H.P., (2005). Collagen: Primer in Structure, Processing and Assembly. Berlin, Germany: Springer:56.
[27] Royce, P.M. and Steinmann, B., (2003). Connective Tissue and Its Heritable Disorders: Molecular, Genetic, and Medical Aspects. New York: Wiley.
[28] Fratzl, P., (2008). Collagen: Structure and Mechanics. New York: Springer. p 1-496.
[29] Buehler, M.J., (2006). Nature Designs Tough Collagen: Explaining the Nanostructure of Collagen Fibrils. PNAS. 103(33):12285-2290.
[30] Morimura, S., Nagata, H., Uemura, Y., Fahmi, A., Shigematsu, T., and Kida, K., (2002). Development of an Effective Process for Utilization of Collagen from Livestock And Fish Waste. Process Biochemistry, 37, 1403–1412.
[31] Yapar, E.A. and Tanrıverdi, S.T., (2016). Yaşlanma Karşıtı Kozmetik Yaklaşımlar ve Ürün Bileşenleri. Balıkesir Sağlık Bilimleri Dergisi, 5(2):99-109.
[32] Kim, S., (2012). Marine cosmeceuticals Trends and Prospects. Taylor and Francis Group, New York, 397s.
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Primary Language	Turkish
Journal Section	Articles
Authors	Erkan Uğurlu 0000-0001-8940-8421 Önder Duysak 0000-0002-7484-3102 Eyüp İlker Saygılı 0000-0002-0102-4237 Sinem Uğur 0000-0003-4309-7415 Selin Sayın 0000-0002-7497-388X
Publication Date	January 31, 2020
Published in Issue	Year 2020 Volume: 15 Issue: 1

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APA	Uğurlu, E., Duysak, Ö., Saygılı, E. İ., Uğur, S., et al. (2020). Denizel Omurgasız Canlılardan Elde Edilen Kolajenler ve Kullanım Alanları. Ecological Life Sciences, 15(1), 24-35.
AMA	Uğurlu E, Duysak Ö, Saygılı Eİ, Uğur S, Sayın S. Denizel Omurgasız Canlılardan Elde Edilen Kolajenler ve Kullanım Alanları. NWSA. January 2020;15(1):24-35.
Chicago	Uğurlu, Erkan, Önder Duysak, Eyüp İlker Saygılı, Sinem Uğur, and Selin Sayın. “Denizel Omurgasız Canlılardan Elde Edilen Kolajenler Ve Kullanım Alanları”. Ecological Life Sciences 15, no. 1 (January 2020): 24-35.
EndNote	Uğurlu E, Duysak Ö, Saygılı Eİ, Uğur S, Sayın S (January 1, 2020) Denizel Omurgasız Canlılardan Elde Edilen Kolajenler ve Kullanım Alanları. Ecological Life Sciences 15 1 24–35.
IEEE	E. Uğurlu, Ö. Duysak, E. İ. Saygılı, S. Uğur, and S. Sayın, “Denizel Omurgasız Canlılardan Elde Edilen Kolajenler ve Kullanım Alanları”, NWSA, vol. 15, no. 1, pp. 24–35, 2020.
ISNAD	Uğurlu, Erkan et al. “Denizel Omurgasız Canlılardan Elde Edilen Kolajenler Ve Kullanım Alanları”. Ecological Life Sciences 15/1 (January 2020), 24-35.
JAMA	Uğurlu E, Duysak Ö, Saygılı Eİ, Uğur S, Sayın S. Denizel Omurgasız Canlılardan Elde Edilen Kolajenler ve Kullanım Alanları. NWSA. 2020;15:24–35.
MLA	Uğurlu, Erkan et al. “Denizel Omurgasız Canlılardan Elde Edilen Kolajenler Ve Kullanım Alanları”. Ecological Life Sciences, vol. 15, no. 1, 2020, pp. 24-35.
Vancouver	Uğurlu E, Duysak Ö, Saygılı Eİ, Uğur S, Sayın S. Denizel Omurgasız Canlılardan Elde Edilen Kolajenler ve Kullanım Alanları. NWSA. 2020;15(1):24-35.

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