Hidrólise controlada de proteínas do soro de queijo usando carboxipeptidase A e alcalase® imobilizadas multipontualmente em agarose.
| Autor(a) principal: | |
|---|---|
| Data de Publicação: | 2003 |
| Tipo de documento: | Tese |
| Idioma: | por |
| Título da fonte: | Repositório Institucional da UFSCAR |
| Texto Completo: | https://repositorio.ufscar.br/handle/ufscar/3897 |
Resumo: | High value food protein hydrolysates can be obtained by sequential hydrolysis of proteins with trypsin, chymotrypsin, carboxypeptidase A (CPA) and Alcalase® (commercial preparation of subtilisin). For the process to be economically feasible, immobilized and stabilized enzymes should be used, and the kinetics of the reactions with this kind of biocatalyst must be known. To contribute to the development of such a process, this work focused on preparing stable CPA and Alcalase® derivatives, and on studying the kinetics of hydrolysis of polypeptides. These polypeptides were produced after the sequential hydrolysis of cheese whey proteins with trypsin and chymotrypsin. Cross-linked agarose beads (6% w/w for CPA, and 10% w/w for Alcalase®) were used as immobilization support, and different methods of activation and immobilization conditions were studied. A highly activated glyoxyl-agarose support (75 and 210 µeqv of aldehyde groups per milliliter of support, respectively for CPA and Alcalase®), 25oC, pH 10.05, and longer contact time (48 hours for CPA and 96 hours for Alcalase®), provided the best derivatives. CPA-glyoxyl agarose-6% and Alcalase®-glyoxyl agarose-10% derivatives were ca. 213- and 515-fold more stable than the soluble enzymes. These stabilized derivatives retained 42% (for CPA-glyoxyl agarose- 6%) and 54% (for Alcalase®-glyoxyl agarose-10%) of the immobilized activity, assessed with small substrates (hippuryl-L-Phe for CPA, and Boc-Ala-ONp for Alcalase®) and large substrates (Phe carboxy-terminal polypeptides for CPA, and casein for Alcalase®). These results showed that all activity losses were caused by the distortion of the immobilized enzyme molecule, due to the enzyme-support multi-interaction. Derivatives prepared using glutaraldehyde-agarose presented spatial hindrances when hydrolysis of macromolecular substrates was taking place. The amino acid analysis of acid hydrolysates of the soluble and immobilized enzymes (for the more stable derivatives) showed that ca. 30 and 40%, for CPA and Alcalase®, of the lysine residues were linked to the support, suggesting that there is intense multi-point interactions between enzyme and support, through covalent linkages. The temperatures for maximum hydrolysis rates, using respectively stabilized CPA and Alcalase® derivatives, were 20oC and 10oC higher than the ones obtained using soluble enzymes. The most stable CPA-glyoxyl derivative could efficiently be used for polypeptides (cheese whey proteins hydrolyzed with trypsin and chymotrypsin) hydrolysis at high temperatures (e.g., 60oC), releasing ca. 2-fold more aromatic amino acids (Tyr, Phe and Trp) than the soluble enzyme, under the same operational conditions. The casein degree of hydrolysis, at 80oC, obtained using the most stable Alcalase®-glyoxyl derivative, was 2-fold higher than the one obtained with the soluble enzyme. Hence, the produced derivatives allow the design of a continuous process for the production of protein hydrolysates, which are composed of small peptides and have a low concentration of aromatic amino acids. This process can use higher temperature, avoiding microbial growth in the reaction medium. The C-terminal residues hydrolysis at 45oC (pH 7.0), catalyzed by CPA-glyoxyl, could be adequately represented by Michaelis-Menten kinetics, with substrate and product inhibition. The kinetic model was expressed in terms of C-terminal peptide bonds that can be hydrolyzed by CPA, regardless of the amino acid released. The concentration of each released amino acid as a function of the time of reaction could be well fitted by empirical models (hyperbolic or exponential decay). Hence, from the kinetics of total hydrolysis, it is possible to estimate the concentration of each amino acid as function of time. The hydrolysis catalyzed by the highly-loaded CPA-glyoxyl agarose-6% derivative was not limited by intra-particle diffusion resistance. The hydrolysis of peptides (long-time batch) at 50oC (pH 9.5), catalyzed by Alcalase®-glyoxyl agarose-10% derivative, could be adequately represented by Michaelis-Menten kinetics with product inhibition, and the kinetic parameters Vmax, KM e KI were correlated against the substrate initial degree of hydrolysis (total degree of hydrolysis obtained by previous action of trypsin and chymotrypsin on cheese whey proteins). Long-time batch hydrolyses, catalyzed by highly-loaded Alcalase-glyoxyl agarose-10% derivative, presented diffusion effects, with effectiveness coefficient, ηI, of ca. 0.5. |
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Tardioli, Paulo WaldirGiordano, Raquel de Lima Camargohttp://genos.cnpq.br:12010/dwlattes/owa/prc_imp_cv_int?f_cod=K4780181P0http://genos.cnpq.br:12010/dwlattes/owa/prc_imp_cv_int?f_cod=K4790436Z857a91b28-06b2-4fc7-b127-2a5005569c492016-06-02T19:55:29Z2005-01-052016-06-02T19:55:29Z2003-08-22TARDIOLI, Paulo Waldir. Hidrólise controlada de proteínas do soro de queijo usando carboxipeptidase A e alcalase® imobilizadas multipontualmente em agarose.. 2003. 204 f. Tese (Doutorado em Ciências Exatas e da Terra) - Universidade Federal de São Carlos, São Carlos, 2003.https://repositorio.ufscar.br/handle/ufscar/3897High value food protein hydrolysates can be obtained by sequential hydrolysis of proteins with trypsin, chymotrypsin, carboxypeptidase A (CPA) and Alcalase® (commercial preparation of subtilisin). For the process to be economically feasible, immobilized and stabilized enzymes should be used, and the kinetics of the reactions with this kind of biocatalyst must be known. To contribute to the development of such a process, this work focused on preparing stable CPA and Alcalase® derivatives, and on studying the kinetics of hydrolysis of polypeptides. These polypeptides were produced after the sequential hydrolysis of cheese whey proteins with trypsin and chymotrypsin. Cross-linked agarose beads (6% w/w for CPA, and 10% w/w for Alcalase®) were used as immobilization support, and different methods of activation and immobilization conditions were studied. A highly activated glyoxyl-agarose support (75 and 210 µeqv of aldehyde groups per milliliter of support, respectively for CPA and Alcalase®), 25oC, pH 10.05, and longer contact time (48 hours for CPA and 96 hours for Alcalase®), provided the best derivatives. CPA-glyoxyl agarose-6% and Alcalase®-glyoxyl agarose-10% derivatives were ca. 213- and 515-fold more stable than the soluble enzymes. These stabilized derivatives retained 42% (for CPA-glyoxyl agarose- 6%) and 54% (for Alcalase®-glyoxyl agarose-10%) of the immobilized activity, assessed with small substrates (hippuryl-L-Phe for CPA, and Boc-Ala-ONp for Alcalase®) and large substrates (Phe carboxy-terminal polypeptides for CPA, and casein for Alcalase®). These results showed that all activity losses were caused by the distortion of the immobilized enzyme molecule, due to the enzyme-support multi-interaction. Derivatives prepared using glutaraldehyde-agarose presented spatial hindrances when hydrolysis of macromolecular substrates was taking place. The amino acid analysis of acid hydrolysates of the soluble and immobilized enzymes (for the more stable derivatives) showed that ca. 30 and 40%, for CPA and Alcalase®, of the lysine residues were linked to the support, suggesting that there is intense multi-point interactions between enzyme and support, through covalent linkages. The temperatures for maximum hydrolysis rates, using respectively stabilized CPA and Alcalase® derivatives, were 20oC and 10oC higher than the ones obtained using soluble enzymes. The most stable CPA-glyoxyl derivative could efficiently be used for polypeptides (cheese whey proteins hydrolyzed with trypsin and chymotrypsin) hydrolysis at high temperatures (e.g., 60oC), releasing ca. 2-fold more aromatic amino acids (Tyr, Phe and Trp) than the soluble enzyme, under the same operational conditions. The casein degree of hydrolysis, at 80oC, obtained using the most stable Alcalase®-glyoxyl derivative, was 2-fold higher than the one obtained with the soluble enzyme. Hence, the produced derivatives allow the design of a continuous process for the production of protein hydrolysates, which are composed of small peptides and have a low concentration of aromatic amino acids. This process can use higher temperature, avoiding microbial growth in the reaction medium. The C-terminal residues hydrolysis at 45oC (pH 7.0), catalyzed by CPA-glyoxyl, could be adequately represented by Michaelis-Menten kinetics, with substrate and product inhibition. The kinetic model was expressed in terms of C-terminal peptide bonds that can be hydrolyzed by CPA, regardless of the amino acid released. The concentration of each released amino acid as a function of the time of reaction could be well fitted by empirical models (hyperbolic or exponential decay). Hence, from the kinetics of total hydrolysis, it is possible to estimate the concentration of each amino acid as function of time. The hydrolysis catalyzed by the highly-loaded CPA-glyoxyl agarose-6% derivative was not limited by intra-particle diffusion resistance. The hydrolysis of peptides (long-time batch) at 50oC (pH 9.5), catalyzed by Alcalase®-glyoxyl agarose-10% derivative, could be adequately represented by Michaelis-Menten kinetics with product inhibition, and the kinetic parameters Vmax, KM e KI were correlated against the substrate initial degree of hydrolysis (total degree of hydrolysis obtained by previous action of trypsin and chymotrypsin on cheese whey proteins). Long-time batch hydrolyses, catalyzed by highly-loaded Alcalase-glyoxyl agarose-10% derivative, presented diffusion effects, with effectiveness coefficient, ηI, of ca. 0.5.Hidrolisados protéicos de alto valor agregado podem ser obtidos através da hidrólise seqüencial de proteínas com tripsina, quimotripsina, carboxipeptidase A (CPA) e Alcalase® (preparação comercial de subtilisina). A viabilidade econômica do processo requer a utilização de enzimas imobilizadas e estabilizadas e o conhecimento da cinética das reações catalisadas com esse tipo de biocatalisador. Visando contribuir para o desenvolvimento de tal processo, os objetivos deste trabalho foram preparar derivados estáveis de CPA e Alcalase® e estudar a cinética da hidrólise de polipeptídios. Esses polipeptídios foram produzidos por hidrólise seqüencial de proteínas do soro de queijo com tripsina e quimotripsina. Utilizandose agarose entrecruzada (6% p/p para CPA e 10% p/p para Alcalase®) como suporte de imobilização, foram estudados diferentes métodos de ativação e condições de imobilização. Suportes glioxil-agarose altamente ativados (75 e 210 µeqv de grupos aldeídos por mililitro de suporte, respectivamente para CPA e Alcalase®) 25oC, pH 10,05 e tempo prolongado de contato (48 horas para CPA e 96 horas para Alcalase®) produziram os melhores derivados. Os derivados CPA-glioxil agarose-6% e Alcalase®-glioxil agarose-10% eram aproximadamente 213 e 515 vezes mais estáveis que as respectivas enzimas na forma solúvel. Esses derivados estabilizados retiveram 42% (para CPA-glioxil agarose-6%) e 54% (para Alcalase®-glioxil agarose-10%) da atividade imobilizada, medidas com substratos de menor massa molecular (hipuril-L-Phe para CPA, e Boc-Ala-ONp para Alcalase®) e substratos de maior massa molecular (polipeptídios com Phe carboxi-terminal para CPA, e caseína para Alcalase®). Esses resultados mostraram que toda a perda de atividade estava associada à distorção da molécula de enzima imobilizada, devido a multi-interação enzima-suporte. Derivados preparados em glutaraldeído-agarose-6% apresentaram impedimentos estéricos na hidrólise de substratos macromoleculares. A análise de aminoácidos de hidrolisados ácidos das enzimas solúveis e imobilizadas (para os derivados mais estáveis) mostrou que aproximadamente 30 e 40%, para CPA e Alcalase®, dos resíduos de lisina ligaram-se no suporte, sugerindo a existência de uma intensa ligação covalente multipontual entre a enzima e o suporte. As temperaturas de máximas taxas de hidrólise, usando respectivamente os derivados estabilizados de CPA e Alcalase®, foram 20oC e 10oC mais elevadas que aquelas obtidas para as respectivas enzimas solúveis. O derivado CPA-glioxil mais estável pôde ser eficientemente utilizado na hidrólise de polipeptídios (proteínas do soro de queijo hidrolisadas com tripsina e quimotripsina) a altas temperaturas (por exemplo, 60oC), liberando duas vezes mais aminoácidos aromáticos (Tyr, Phe e Trp) do que a enzima solúvel, sob as mesmas condições operacionais. O grau de hidrólise de caseína, a 80oC, obtido com o derivado Alcalase®-glioxil mais estável, foi duas vezes maior que aquele obtido com a enzima solúvel. Assim, os derivados produzidos permitem o projeto de um processo contínuo para a produção de hidrolisados protéicos, compostos de pequenos peptídios e com uma baixa concentração de aminoácidos aromáticos. Esse processo pode ser conduzido a alta temperatura, evitando-se assim problemas de contaminação microbiana do meio reacional. A hidrólise de resíduos carboxi-terminais a 45oC (pH 7,0), catalisada pelo derivado CPA-glioxil, pôde ser adequadamente representada por cinética de Michaelis-Menten, com inibição pelo substrato e produto. O modelo cinético foi representado em termos de ligações peptídicas carboxiterminais hidrolisáveis pela CPA, sem considerar-se a natureza do resíduo a ser liberado. A concentração de cada aminoácido liberado em função do tempo de hidrólise pôde ser ajustada por modelos empíricos (hiperbólico e decaimento exponencial). Assim, a partir da cinética de hidrólise total, é possível estimar-se a concentração de cada aminoácido em função do tempo de hidrólise. A hidrólise catalisada pelo derivado CPA-glioxil agarose-6%, com alta carga enzimática imobilizada, não foi limitada pela resistência difusional intrapartícula. A hidrólise de peptídios (bateladas de longa duração) a 50oC (pH 9,5), catalisada pelo derivado Alcalase®-glioxil agarose-10%, pôde ser adequadamente representada por cinética de Michaelis-Menten com inibição pelo produto, e os parâmetros cinéticos Vmax, KM e KI foram correlacionados com o grau de hidrólise inicial do substrato (grau de hidrólise total obtido pela prévia ação de tripsina e quimotripsina sobre as proteínas do soro de queijo). Hidrólises em batelada de longa duração, catalisadas por Alcalase®-glioxil agarose-10% com alta carga enzimática imobilizada, apresentaram efeitos de difusão, com um fator de efetividade, ηI, de aproximadamente 0,5.Universidade Federal de Minas Geraisapplication/pdfporUniversidade Federal de São CarlosPrograma de Pós-Graduação em Engenharia Química - PPGEQUFSCarBRTecnologia de enzimasAlcalase®Carboxipeptidase AGlioxil - agaroseCinética de hidrólise de polipeptidiosENGENHARIAS::ENGENHARIA QUIMICAHidrólise controlada de proteínas do soro de queijo usando carboxipeptidase A e alcalase® imobilizadas multipontualmente em agarose.info:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/doctoralThesis-1-187b60e6c-591e-4a38-94f3-e75e2beebea0info:eu-repo/semantics/openAccessreponame:Repositório Institucional da UFSCARinstname:Universidade Federal de São Carlos (UFSCAR)instacron:UFSCARORIGINALDoutPWT.pdfapplication/pdf1538718https://repositorio.ufscar.br/bitstream/ufscar/3897/1/DoutPWT.pdfa2cfebb6aac530f7f09069137eaebc60MD51THUMBNAILDoutPWT.pdf.jpgDoutPWT.pdf.jpgIM Thumbnailimage/jpeg7475https://repositorio.ufscar.br/bitstream/ufscar/3897/2/DoutPWT.pdf.jpg7c29064853ff21b1fcf286bec3199387MD52ufscar/38972023-09-18 18:30:58.326oai:repositorio.ufscar.br:ufscar/3897Repositório InstitucionalPUBhttps://repositorio.ufscar.br/oai/requestopendoar:43222023-09-18T18:30:58Repositório Institucional da UFSCAR - Universidade Federal de São Carlos (UFSCAR)false |
| dc.title.por.fl_str_mv |
Hidrólise controlada de proteínas do soro de queijo usando carboxipeptidase A e alcalase® imobilizadas multipontualmente em agarose. |
| title |
Hidrólise controlada de proteínas do soro de queijo usando carboxipeptidase A e alcalase® imobilizadas multipontualmente em agarose. |
| spellingShingle |
Hidrólise controlada de proteínas do soro de queijo usando carboxipeptidase A e alcalase® imobilizadas multipontualmente em agarose. Tardioli, Paulo Waldir Tecnologia de enzimas Alcalase® Carboxipeptidase A Glioxil - agarose Cinética de hidrólise de polipeptidios ENGENHARIAS::ENGENHARIA QUIMICA |
| title_short |
Hidrólise controlada de proteínas do soro de queijo usando carboxipeptidase A e alcalase® imobilizadas multipontualmente em agarose. |
| title_full |
Hidrólise controlada de proteínas do soro de queijo usando carboxipeptidase A e alcalase® imobilizadas multipontualmente em agarose. |
| title_fullStr |
Hidrólise controlada de proteínas do soro de queijo usando carboxipeptidase A e alcalase® imobilizadas multipontualmente em agarose. |
| title_full_unstemmed |
Hidrólise controlada de proteínas do soro de queijo usando carboxipeptidase A e alcalase® imobilizadas multipontualmente em agarose. |
| title_sort |
Hidrólise controlada de proteínas do soro de queijo usando carboxipeptidase A e alcalase® imobilizadas multipontualmente em agarose. |
| author |
Tardioli, Paulo Waldir |
| author_facet |
Tardioli, Paulo Waldir |
| author_role |
author |
| dc.contributor.authorlattes.por.fl_str_mv |
http://genos.cnpq.br:12010/dwlattes/owa/prc_imp_cv_int?f_cod=K4790436Z8 |
| dc.contributor.author.fl_str_mv |
Tardioli, Paulo Waldir |
| dc.contributor.advisor1.fl_str_mv |
Giordano, Raquel de Lima Camargo |
| dc.contributor.advisor1Lattes.fl_str_mv |
http://genos.cnpq.br:12010/dwlattes/owa/prc_imp_cv_int?f_cod=K4780181P0 |
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57a91b28-06b2-4fc7-b127-2a5005569c49 |
| contributor_str_mv |
Giordano, Raquel de Lima Camargo |
| dc.subject.por.fl_str_mv |
Tecnologia de enzimas Alcalase® Carboxipeptidase A Glioxil - agarose Cinética de hidrólise de polipeptidios |
| topic |
Tecnologia de enzimas Alcalase® Carboxipeptidase A Glioxil - agarose Cinética de hidrólise de polipeptidios ENGENHARIAS::ENGENHARIA QUIMICA |
| dc.subject.cnpq.fl_str_mv |
ENGENHARIAS::ENGENHARIA QUIMICA |
| description |
High value food protein hydrolysates can be obtained by sequential hydrolysis of proteins with trypsin, chymotrypsin, carboxypeptidase A (CPA) and Alcalase® (commercial preparation of subtilisin). For the process to be economically feasible, immobilized and stabilized enzymes should be used, and the kinetics of the reactions with this kind of biocatalyst must be known. To contribute to the development of such a process, this work focused on preparing stable CPA and Alcalase® derivatives, and on studying the kinetics of hydrolysis of polypeptides. These polypeptides were produced after the sequential hydrolysis of cheese whey proteins with trypsin and chymotrypsin. Cross-linked agarose beads (6% w/w for CPA, and 10% w/w for Alcalase®) were used as immobilization support, and different methods of activation and immobilization conditions were studied. A highly activated glyoxyl-agarose support (75 and 210 µeqv of aldehyde groups per milliliter of support, respectively for CPA and Alcalase®), 25oC, pH 10.05, and longer contact time (48 hours for CPA and 96 hours for Alcalase®), provided the best derivatives. CPA-glyoxyl agarose-6% and Alcalase®-glyoxyl agarose-10% derivatives were ca. 213- and 515-fold more stable than the soluble enzymes. These stabilized derivatives retained 42% (for CPA-glyoxyl agarose- 6%) and 54% (for Alcalase®-glyoxyl agarose-10%) of the immobilized activity, assessed with small substrates (hippuryl-L-Phe for CPA, and Boc-Ala-ONp for Alcalase®) and large substrates (Phe carboxy-terminal polypeptides for CPA, and casein for Alcalase®). These results showed that all activity losses were caused by the distortion of the immobilized enzyme molecule, due to the enzyme-support multi-interaction. Derivatives prepared using glutaraldehyde-agarose presented spatial hindrances when hydrolysis of macromolecular substrates was taking place. The amino acid analysis of acid hydrolysates of the soluble and immobilized enzymes (for the more stable derivatives) showed that ca. 30 and 40%, for CPA and Alcalase®, of the lysine residues were linked to the support, suggesting that there is intense multi-point interactions between enzyme and support, through covalent linkages. The temperatures for maximum hydrolysis rates, using respectively stabilized CPA and Alcalase® derivatives, were 20oC and 10oC higher than the ones obtained using soluble enzymes. The most stable CPA-glyoxyl derivative could efficiently be used for polypeptides (cheese whey proteins hydrolyzed with trypsin and chymotrypsin) hydrolysis at high temperatures (e.g., 60oC), releasing ca. 2-fold more aromatic amino acids (Tyr, Phe and Trp) than the soluble enzyme, under the same operational conditions. The casein degree of hydrolysis, at 80oC, obtained using the most stable Alcalase®-glyoxyl derivative, was 2-fold higher than the one obtained with the soluble enzyme. Hence, the produced derivatives allow the design of a continuous process for the production of protein hydrolysates, which are composed of small peptides and have a low concentration of aromatic amino acids. This process can use higher temperature, avoiding microbial growth in the reaction medium. The C-terminal residues hydrolysis at 45oC (pH 7.0), catalyzed by CPA-glyoxyl, could be adequately represented by Michaelis-Menten kinetics, with substrate and product inhibition. The kinetic model was expressed in terms of C-terminal peptide bonds that can be hydrolyzed by CPA, regardless of the amino acid released. The concentration of each released amino acid as a function of the time of reaction could be well fitted by empirical models (hyperbolic or exponential decay). Hence, from the kinetics of total hydrolysis, it is possible to estimate the concentration of each amino acid as function of time. The hydrolysis catalyzed by the highly-loaded CPA-glyoxyl agarose-6% derivative was not limited by intra-particle diffusion resistance. The hydrolysis of peptides (long-time batch) at 50oC (pH 9.5), catalyzed by Alcalase®-glyoxyl agarose-10% derivative, could be adequately represented by Michaelis-Menten kinetics with product inhibition, and the kinetic parameters Vmax, KM e KI were correlated against the substrate initial degree of hydrolysis (total degree of hydrolysis obtained by previous action of trypsin and chymotrypsin on cheese whey proteins). Long-time batch hydrolyses, catalyzed by highly-loaded Alcalase-glyoxyl agarose-10% derivative, presented diffusion effects, with effectiveness coefficient, ηI, of ca. 0.5. |
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2003 |
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2003-08-22 |
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2005-01-05 2016-06-02T19:55:29Z |
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2016-06-02T19:55:29Z |
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TARDIOLI, Paulo Waldir. Hidrólise controlada de proteínas do soro de queijo usando carboxipeptidase A e alcalase® imobilizadas multipontualmente em agarose.. 2003. 204 f. Tese (Doutorado em Ciências Exatas e da Terra) - Universidade Federal de São Carlos, São Carlos, 2003. |
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TARDIOLI, Paulo Waldir. Hidrólise controlada de proteínas do soro de queijo usando carboxipeptidase A e alcalase® imobilizadas multipontualmente em agarose.. 2003. 204 f. Tese (Doutorado em Ciências Exatas e da Terra) - Universidade Federal de São Carlos, São Carlos, 2003. |
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