Baran Enes GULER, Elif DEMİRKAN, Tuba SEVGİ

Bu çalışmada, elektrospin yöntemiyle yüksek yüzey alanına sahip, glisin, tirozin ve glutamik asit aminoasitleri ile oluşturulmuş poliamid 6 polimer yüzeyler üretilmiş ve liyofilize Bacillus subtilis E6-5 proteaz ve ticari proteaz enzimleri nanofibriller üzerinde immobilize edilmiştir. Enzimlerin yeniden kullanılabilirliği araştırıldı. Enzimlerin immobilizasyon verimlilikleri yaklaşık olarak % 50-55 arasındaydı. Liyofilize Bacillus proteazı ile yapılan çalışmalarda glutaraldehitle aktifleştirilmiş PA6 nanolifler ve glutaraldehitle aktifleştirilmeyen PA6 nanoliflerde glutamik asit aminoasidi varlığında immobilizasyonun daha başarılı olduğu saptanmıştır. Glutaraldehit ile aktifleştirilmemiş ve aktifleştirilmiş yüzeylerde immobilize edilen liyofilize proteaz enziminin 4 kez kullanımı olmasına rağmen, en iyi işlevsel stabilite 2 kez kullanım ile elde edilmiştir. Saf PA6/glutamik asit nanoliflerinde iki tekrarlı kullanım sonucu enzimin immobilizasyon verimi % 38 olarak bulunmuştur. Glutaraldehitle aktifleştirilmiş PA6 nanoliflerde de PA6/glutamik asit nanolif yüzeyleri iki tekrarlı kullanım sonucu enzimin immobilizasyon verimi % 65 olarak bulunmuştur. Nanoliflerin glutaraldehitle aktifleştirmesi sonucu enzim immobilizasyon verimi iki kat arttırılmıştır. Ticari proteaz ile yapılan çalışmalarda ise glutaraldehitle aktifleştirilmemiş nanolif yüzeylerde enzimin 6 kez kullanımı olmasına rağmen en işlevsel stabilite 3 tekrarlı kullanımda elde edilmiştir. En başarılı immobilizasyon verimi PA6 nanoliflerde % 58 olarak bulunmuştur. Glutaraldehitle aktifleştirilmiş PA6 nanoliflerde de enzim 6 kez kullanım bulmuş fakat işlevsel stabilite 4 tekrarlı kullanıma kadar korunmuştur.

IMMOBILIZATION OF Bacillus subtilis E6-5 PROTEASE AND COMMERCIAL PROTEASE IN NANOFIBRILS CONTAINING DIFFERENT AMINO ACIDS

In this study, polyamide 6 polymer surfaces that have a high surface area were produced by electrospinning method with the participation of Glycine, Tyrosine and Glutamic acid amino acids, and lyophilized Bacillus subtilis E6-5 protease and commercial protease enzymes were immobilized on nanofibrils. Enzyme reusability were investigated. The immobilization efficiencies of the enzymes were approximately between 50-55 %. In studies with lyophilized Bacillus protease, glutaraldehyde activated PA6 nanofibrils and glutaraldehyde unactivated PA6 nanofibrils were found to be more immobilized in the presence of Glutamic acid. Although the lyophilized protease enzyme immobilized on non-glutaraldehyde activated and activated surfaces has been used 4 times, the best functional stability has been achieved with 2 times use. In pure PA6/Glutamic acid nanofibrils, the immobilization yield of the two times used enzymes was found to be 38 %. In glutaraldehyde-activated PA6 nanofibrils, the PA6/Glutamic acid nanofibril surfaces were found to have 65 % immobilization yield of the two repetitive used enzymes. The enzyme immobilization efficiency has been doubled by glutaraldehyde activation of the nanofibrils. In studies with commercial protease, the most functional stability was obtained for 3 repeated uses, although the enzyme was used 6 times on the non-glutaraldehyde activated nanofibril surfaces. The most successful immobilization was found in 58 % of PA6 nanofibrils. In glutaraldehyde-activated PA6 nanofibrils, the enzyme was found to be used 6 times, but the functional stability was maintained as much as 4 times of repeated use.

Keywords:

immobilization elektrospinnig, protease, reusability,

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