Your search keyword '"Periodate"' showing total 5 results

1. Immobilization of chemically modified horse radish peroxidase within activated alginate beads

Author

Spasojević Dragica, Prokopijević Miloš, Prodanović Olivera, Pirtea Marilen Gabriel, Radotić Ksenija, and Prodanović Radivoje

Subjects

periodate, ethylene diamine, peroxidase, immobilized, Chemical technology, TP1-1185

Abstract

Immobilization of horse radish peroxidase (HRP) within alginate beads was improved by chemical modification of the enzyme and polysaccharide chains. HRP and alginate were oxidized by periodate and subsequently modified with ethylenediamine. Highest specific activity of 0.43 U/ml of gel and 81 % of bound enzyme activity was obtained using aminated HRP and alginate oxidized by periodate. Immobilized enzyme retained 75 % of original activity after 2 days of incubation in 80 % (v/v) dioxane and had increased activity at basic pH values compared to native enzyme. During repeated use in batch reactor for pyrogallol oxidation immobilized peroxidase retained 75 % of original activity. [Projekat Ministarstva nauke Republike Srbije, br. ON173017 i br. ON172049]

Published

2014

2. Characterization of amyloglucosidase immobilized on the copolymer of ethylene glycol dimethacrylate and glycidyl methacrylate in simulated industrial conditions

Author

Milosavić Nenad B., Prodanović Radivoje M., Jovanović Slobodan M., Maksimović Vuk M., and Vujčić Zoran M.

Subjects

glucoamylase, enzyme reactor, periodate, poly (GMA-co-EGDMA), immobilization, stability, Chemical technology, TP1-1185

Abstract

The application of amyloglucosidase immobilized on the macroporous co-polymer of ethylene glycol dimethacrylate and glycidyl methacrylate (poly (GMA-co-EGDMA)) in an enzyme reactor was shown. The higher thermostability of immobilized glucoamylases than the soluble one was demonstrated. Immobilized amyloglucosidase obtained by the periodate method shows two times higher thermo stability than the soluble form. Glucoamylases immobilized on poly (GMA-co-EGDMA) have good mechanical and chemical features in the reactor and when applied in a continuous flow reactor for 28 days no changes are observed. In this period periodate immobilized amyloglucosidase shows no decrease in activity. It showed potential for the continuous production of glucose from starch over a prolonged period of time.

Published

2004

3. Immobilization of invertase and glucoamylase on a macroporous copolymer of etyleneglycoldimethacrylate and glycidyl methacrylate and potential applications in biotechnology

Author

Prodanović Radivoje M., Milosavić Nenad B., Jovanović Slobodan M., and Vujčić Zoran M.

Subjects

Invertase, Glucoamylase, Periodate, Poly(GMA-co-EGDMA), Immobilization, Stability, Glycoside, Organic solvent, Chemical technology, TP1-1185

Abstract

The optimal conditions for the immobilization of invertase and glucoamylasewere found via their carbohydrate moiety on a macroporous copolymer of ehtyleneglycoldimethacry late and glycidylmethacrylate. Almost all of the added enzyme was bound to the polymer by increasing the time of incubation of the oxidized enzyme with polymer. A specific activity of 5500 U/g for invertase was obtained and 1100 U/g for glucoamylase. The specific productivity for invertase in a packed bed reactor was 3.5 kg/lh and for glucoamylase 1.9 kg/lh. During continuous use in a packed bed the reactor operational half life for invertase was 290 days, while no decrease in activity was observed for glucoamylase. In 50% (v/v) ethanol the immobilized enzymes were five to ten times more stable, and more than 200 times more stable in 25% (v/v) dioxane. The immobilized enzymes retained all activity in petroleum ether after 3 days of incubation. Because of their higher stability over native enzymes, and the large surface area of the polymer immobilized glucoamylase and invertase could be more useful for glycoside synthesis in non-aqueous solvents than native ones.

Published

2003

4. Immobilization of soybean peroxidase (Glycine max) onto macroporous glycidyl-methacrylate and chemically modified pectin

Author

Prokopijević, Miloš M., Prodanović, Radivoje, Radotić Hadži-Manić, Ksenija, and Gavrović-Jankulović, Marija

Subjects

pectin, perjodat, Soybean peroxidase, imobilizacija enzima, hidrogel, glicidil metakrilat, periodate, glycidyl-methacrylate, peroksidaza iz soje, glutaraldehyde, glutaraldehid, pektin, hydrogel, enzyme immobilization

Abstract

Peroksidaza iz soje (SBP, E.C. 1.11.1.7) je enzim koji pripada klasi III biljnih peroksidaza i katalizuje oksidaciju i polimerizaciju različitih fenolnih jedinjenja u prisustvu vodonik peroksida kao supstrata. Nalazi se u semenom omotaču soje koji predstavlja jeftini nusproizvod i polazni materijal za izolovanje velike količine sirovog enzima. Izolovana SBP je imobilizovana primenom dve kovalentne metode na seriju makroporoznih kopolimera poli(GMA-co-EGDMA) različitih dijametara pora. Glutaraldehidni metod imobilizacije se pokazao boljim od perjodatnog a najveća specifična aktivnost od 23 IU/g dobijena je na kopolimeru veličine pora od 120 nm. Imobilizovana peroksidaza pokazala je veću termalnu stabilnost i stabilnost u organskom rastvaraču, aktivnost u širem opsegu pH i 2,86 puta veću Km vrednost za pirogalol u odnosu na rastvorni enzim. Sintetisana je serija modifikovanih pektina oksidacijom perjodatom u molarnom odnosu od 2,5 do 20 mol% i naknadnom reduktivnom aminacijom tiraminom i cijanoborhidridom. Dobijeni tiramin-pektini prave stabilne hidrogelove umrežavanjem fenolnih grupa u reakciji katalizovanoj peroksidazama u prisustvu vodonik peroksida. SBP je uspešno imobilizovana unutar mikro-kuglica hidrogela nastalih enzimskom polimerizacijom modifikovanog pektina u emulziji sa najvećom specifičnom aktivnošću postignutom na tiramin-pektinu oksidovanom 5 mol% perjodatom. Imobilizovana SBP je pored šireg pH optimuma pokazala i veću termalnu stabilnost i stabilnost u organskom rastvaraču u odnosu na slobodan enzim. Mikrokuglice sa imobilizovanom SBP zadržale su 50% početne aktivnosti nakon 7 ciklusa ponovne upotrebe za oksidaciju pirogalola u bač reaktoru. Pod optimalnim uslovima sa unutrašnjom dostavom vodonik peroksida postignuto je uklanjanje fenola od 64% imobilizovanom SBP na poli(GMA-co-EGDMA) veličine pora od 120 nm. Soybean peroxidase (SBP, E.C. 1.11.1.7) is an enzyme that belongs to class III of plant peroxidases that catalyses oxidation and polymerization of various phenolic compounds in the presence of hydrogen peroxide as substrate. It's located in the soybean seed hulls, an inexpensive byproduct and excellent material for isolation of large amounts of crude enzyme. SBP was immobilized by using two covalent methods onto a series of macroporous copolymers of poly(GMA-co-EGDMA) with various pore diameters. Glutaraldehyde immobilization method proved to be better than periodate with highest specific activity of 23 IU/g obtained with copolymer with pore size of 120 nm. Compared to the soluble enzyme, immobilized peroxidase showed increased thermal and organic solvent stability, broader pH activity range and 2.86 times higher Km value for pyrogallol. Series of modified pectins have been synthesized by oxidation with periodate in molar ratios from 2.5 to 20 mol% and subsequent reductive amination with tyramine and cyanobohrhydride. Obtained tyramnine-pectine made stable hydrogels by crosslinking phenol groups in a peroxidase catalysed reaction in the presence of hydrogen peroxide. SBP was immobilized within hydrogel microbeads created in enzyme polymerization of modified pectin in emulsion with highest specific activity achieved with tyramine-pectin oxidized by 5 mol% of periodate. Immobilized SBP in addition of having wider pH optimum showed higher thermal and organic solvent stability compared to the free enzyme. SBP bound in microbeads retained 50% of the original activity after 7 cycles of repeated usage for pyrogallol oxidation in batch reactor. Under optimal conditions with internal hydrogen peroxide delivery phenol removal of 64% has been achieved with SBP immobilized onto poly(GMA-co-EGDMA) with pore size of 120 nm.

Published

2017

5. Immobilization of soybean peroxidase (Glycine max) onto macroporous glycidyl-methacrylate and chemically modified pectin

Author

Prokopijević, Miloš, Prodanović, Radivoje, Radotić Hadži-Manić, Ksenija, and Gavrović-Jankulović, Marija

Subjects

pectin, perjodat, Soybean peroxidase, imobilizacija enzima, hidrogel, glicidil metakrilat, periodate, glycidyl-methacrylate, glutaraldehyde, peroksidaza iz soje, glutaraldehid, hydrogel, pektin, enzyme immobilization

Abstract

Peroksidaza iz soje (SBP, E.C. 1.11.1.7) je enzim koji pripada klasi III biljnih peroksidaza i katalizuje oksidaciju i polimerizaciju različitih fenolnih jedinjenja u prisustvu vodonik peroksida kao supstrata. Nalazi se u semenom omotaču soje koji predstavlja jeftini nusproizvod i polazni materijal za izolovanje velike količine sirovog enzima.Izolovana SBP je imobilizovana primenom dve kovalentne metode na seriju makroporoznih kopolimera poli(GMA-co-EGDMA) različitih dijametara pora. Glutaraldehidni metod imobilizacije se pokazao boljim od perjodatnog a najveća specifična aktivnost od 23 IU/g dobijena je na kopolimeru veličine pora od 120 nm. Imobilizovana peroksidaza pokazala je veću termalnu stabilnost i stabilnost u organskom rastvaraču, aktivnost u širem opsegu pH i 2,86 puta veću Km vrednost za pirogalol u odnosu na rastvorni enzim.Sintetisana je serija modifikovanih pektina oksidacijom perjodatom u molarnom odnosu od 2,5 do 20 mol% i naknadnom reduktivnom aminacijom tiraminom i cijanoborhidridom. Dobijeni tiramin-pektini prave stabilne hidrogelove umrežavanjem fenolnih grupa u reakciji katalizovanoj peroksidazama u prisustvu vodonik peroksida. SBP je uspešno imobilizovana unutar mikro-kuglica hidrogela nastalih enzimskom polimerizacijom modifikovanog pektina u emulziji sa najvećom specifičnom aktivnošću postignutom na tiramin-pektinu oksidovanom 5 mol% perjodatom. Imobilizovana SBP je pored šireg pH optimuma pokazala i veću termalnu stabilnost i stabilnost u organskom rastvaraču u odnosu na slobodan enzim. Mikrokuglice sa imobilizovanom SBP zadržale su 50% početne aktivnosti nakon 7 ciklusa ponovne upotrebe za oksidaciju pirogalola u bač reaktoru.Pod optimalnim uslovima sa unutrašnjom dostavom vodonik peroksida postignuto je uklanjanje fenola od 64% imobilizovanom SBP na poli(GMA-co-EGDMA) veličine pora od 120 nm. Soybean peroxidase (SBP, E.C. 1.11.1.7) is an enzyme that belongs to class III of plant peroxidases that catalyses oxidation and polymerization of various phenolic compounds in the presence of hydrogen peroxide as substrate. It's located in the soybean seed hulls, an inexpensive byproduct and excellent material for isolation of large amounts of crude enzyme.SBP was immobilized by using two covalent methods onto a series of macroporous copolymers of poly(GMA-co-EGDMA) with various pore diameters. Glutaraldehyde immobilization method proved to be better than periodate with highest specific activity of 23 IU/g obtained with copolymer with pore size of 120 nm. Compared to the soluble enzyme, immobilized peroxidase showed increased thermal and organic solvent stability, broader pH activity range and 2.86 times higher Km value for pyrogallol.Series of modified pectins have been synthesized by oxidation with periodate in molar ratios from 2.5 to 20 mol% and subsequent reductive amination with tyramine and cyanobohrhydride. Obtained tyramnine-pectine made stable hydrogels by crosslinking phenol groups in a peroxidase catalysed reaction in the presence of hydrogen peroxide. SBP was immobilized within hydrogel microbeads created in enzyme polymerization of modified pectin in emulsion with highest specific activity achieved with tyramine-pectin oxidized by 5 mol% of periodate. Immobilized SBP in addition of having wider pH optimum showed higher thermal and organic solvent stability compared to the free enzyme. SBP bound in microbeads retained 50% of the original activity after 7 cycles of repeated usage for pyrogallol oxidation in batch reactor.Under optimal conditions with internal hydrogen peroxide delivery phenol removal of 64% has been achieved with SBP immobilized onto poly(GMA-co-EGDMA) with pore size of 120 nm.

Published

2017