Application of surface response methodology to optimize hydrolysis of wheat gluten and characterization of selected hydrolysate fractions

Drago, Silvina Rosa; González, Rolando J.; Añón, Marı́a Cristina

doi:10.1002/jsfa.3233

Cited by 5 publications

(4 citation statements)

References 15 publications

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“…15851 Standard technique). In order to disperse vital gluten in water and have a uniform suspension, a moderate thermal treatment was carried out according to Drago, González, and Añón (2008). Samples of thermal-treated gluten (TTG) were used as substrate of protein hydrolysis reaction.…”

Section: Reagentsmentioning

confidence: 99%

Structure–mechanism relationship of antioxidant and ACE I inhibitory peptides from wheat gluten hydrolysate fractionated by pH

Cian

Vioque

Drago

2015

Food Research International

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Section: Reagentsmentioning

confidence: 99%

Structure–mechanism relationship of antioxidant and ACE I inhibitory peptides from wheat gluten hydrolysate fractionated by pH

Cian

Vioque

Drago

2015

Food Research International

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“…Thus, enzymatic hydrolysis of WG has been expected as a method resolving gluten allergenicity and producing valuable food materials for use as condiments [3][4][5]. Until now, some studies dealing with the enzymatic hydrolysis of WG and characterization for the resultant hydrolyzates have been reported [6,7]. However, these reports were conducted at ambient pressure and had some limitations with respect to reaction conditions such as reaction time and temperature, duration of hydrolysis, and product yield according to the catalytic properties of the proteases used.…”

Section: Introductionmentioning

confidence: 99%

Production of wheat gluten hydrolyzates by enzymatic process at high pressure

Kim

2017

Food Sci Biotechnol

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A novel process for producing wheat gluten enzyme hydrolyzates (WGEHs) was developed, using combinations of Flavourzyme 500MG, Alcalase 2.4L, Protamex, and Marugoto E at the high pressure of 300 MPa, and the resultant hydrolyzates were analyzed for electrophoretic and hydrolytic properties. It was found that multiple-enzyme treatments increased the proportion of the electrophoretic bands less than 5 kDa in the hydrolyzates greatly both at ambient pressure and 300 MPa compared with one-enzyme hydrolysis. The contents of total soluble solids in the WGEHs increased considerably up to 89.75% according to the increase in the number of enzymes used at 300 MPa compared with 79.37% found for the ambient-pressure hydrolysis. These characteristics together with the contents of soluble nitrogen and free amino acids clearly indicated that the high-pressure enzymatic process of this study is an efficient method for obtaining WGEHs with increased degree of hydrolysis.

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“…Secondly, the hybridization reaction is the other main limitation step of beadbased assays, with similar experimental considerations to planar arrays since the reaction occurs at a solid-liquid interface. Kinetics, target detection specificity and sensitivity in ASO hybridization methods depend highly on the target and probe environment interface [14]. Here, the initial challenge was to optimize a system dependent on a large number of parameters.…”

Section: Introductionmentioning

confidence: 99%

“…The design of experiments (DOE), described as a strategy to plan research using multivariable statistic methods has been scarcely used in biology [15][16][17][18], whereas it is commonly applied to analytical chemistry processes, biosensors and drug delivery system optimization [19][20][21]14]. This study reports the application of response surface methodology (RSM) and multiple response optimization (MRO) to predict optimum experimental conditions for the hybridization of a short oligo 4 fluorescent target to QDEM-DNA probe (Fig.…”

Section: Introductionmentioning

confidence: 99%

Application of multiple response optimization design to quantum dot-encoded microsphere bioconjugates hybridization assay

Thiollet¹,

Bessant²,

Morgan³

2011

Analytical Biochemistry

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The optimization of DNA hybridization for genotyping assays is a complex experimental problem that depends on multiple factors such as assay formats, fluorescent probes, target sequence, experimental conditions, and data analysis. Quantum dot-doped particle bioconjugates have been previously described as fluorescent probes to identify single nucleotide polymorphisms even though this advanced fluorescent material has shown structural instability in aqueous environments. To achieve the optimization of DNA hybridization to quantum dot-doped particle bioconjugates in suspension while maximizing the stability of the probe materials, a nonsequential optimization approach was evaluated. The design of experiment with response surface methodology and multiple optimization response was used to maximize the recovery of fluorescent probe at the end of the assay simultaneously with the optimization of target-probe binding. Hybridization efficiency was evaluated by the attachment of fluorescent oligonucleotides to the fluorescent probe through continuous flow cytometry detection. Optimal conditions were predicted with the model and tested for the identification of single nucleotide polymorphisms. The design of experiment has been shown to significantly improve biochemistry and biotechnology optimization processes. Here we demonstrate the potential of this statistical approach to facilitate the optimization of experimental protocol that involves material science and molecular biology.

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Application of surface response methodology to optimize hydrolysis of wheat gluten and characterization of selected hydrolysate fractions

Cited by 5 publications

References 15 publications

Structure–mechanism relationship of antioxidant and ACE I inhibitory peptides from wheat gluten hydrolysate fractionated by pH

Structure–mechanism relationship of antioxidant and ACE I inhibitory peptides from wheat gluten hydrolysate fractionated by pH

Production of wheat gluten hydrolyzates by enzymatic process at high pressure

Application of multiple response optimization design to quantum dot-encoded microsphere bioconjugates hybridization assay

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