Collagen production from chicken keel bone using acid and enzymatic treatment at a temperature of 30 °C

Cordeiro, Ana Rita Ribeiro de Araújo; Bezerra, Taliana Kênia Alencar; Queiroz, Angela Lima Menêses de; Galvão, Mércia de Sousa; Cavalcanti, Mônica Tejo; Pacheco, Maria Teresa Bertoldo; Madruga, Marta Suely

doi:10.1590/fst.43118

Cited by 10 publications

(6 citation statements)

References 24 publications

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“…Gel permeation chromatography provides information regarding the Mw and molecular weight distribution of deer antler base gelatine as shown in acids before and after hydrolysis and are classified as umami amino acids. This result was consistent with those for gelatine from bones, such as chicken keel bone (Cordeiro et al, 2020) and skipjack tuna bone (Yang, Zhao, Qiu, Chi, & Wang, 2019). Some amino acids, such as aspartic acid, serine, and glutamic acid, were sensitive to hydrolysis and showed a considerable decrease in concentration.…”

Section: Dh and Molecular Weight Distribution Of The Deer Antler Base Gelatine Hydrolysatesupporting

confidence: 87%

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Functional properties and antioxidant activity of gelatine and hydrolysate from deer antler base

Liu

Xia

Mei

et al. 2020

Food Science & Nutrition

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Gelatine was extracted from deer antler base by the hot water method and hydrolyzed with trypsin. A comparison of the properties of gelatine before and after enzymatic hydrolysis showed a decline in the surface hydrophobicity, enhanced thermal stability, broadening of the particle size distribution, a zeta potential shift to a lower pH, reduced foaming and emulsifying properties, and enhanced antioxidant activity. Hydrolysis increased the gelatine antioxidant activity in DPPH and FRAP assays. These results indicate that the functional properties of deer antler base gelatine may be affected by trypsin modification.

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Section: Dh and Molecular Weight Distribution Of The Deer Antler Base Gelatine Hydrolysatesupporting

confidence: 87%

“…Other amino acids, such as cysteine, lysine, histidine, and all the hydrophobic amino acids, controlled the emulsification properties of the emulsified products (Cordeiro et al, 2020).…”

Section: Amino Acid Analysismentioning

confidence: 99%

Functional properties and antioxidant activity of gelatine and hydrolysate from deer antler base

Liu

Xia

Mei

et al. 2020

Food Science & Nutrition

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“…The differences result probably from the age of the chickens (very young 5-week-old broilers were studied, whereas in other studies, the age was over 7 weeks [13]). However, there is no difference in the share of ash per dry matter between our own and other studies [12,14]; this value is low and amounts to about 7%, indicating that the cartilage is not mineralized. In fish and reptile cartilage tissues, the total protein level is higher than in poultry cartilage, ranging from 12% to 15%, which is mainly due to the higher dry matter content of 25-45% [15,16].…”

Section: Chemical Composition Of the Raw Materialscontrasting

confidence: 65%

Characteristics of Reconstituted Collagen Fibers from Chicken Keel Cartilage Depends on Salt Type for Removal of Proteoglycans

2021

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The aim of the presented research was to obtain reconstituted atelocollagen fibers after extraction from poultry cartilage using the pepsin-acidic method in order to remove telopeptides from the tropocollagen. Firstly, we examined the extraction of collagen from the cartilage extracellular matrix (ECM) after proteoglycans (PG) had been removed by the action of salts, i.e., NaCl or chaotropic MgCl2. Additionally, the effects of the salt type used for PG and hyaluronic acid removal on the properties of self-assembled fibers in solutions at pH 7.4 and freeze-dried matrices were investigated. The basic features of the obtained fibers were characterized, including thermal properties using scanning calorimetry, rheological properties using dynamic oscillatory rheometry, and the structure by scanning electron microscopy. The fibers obtained after PG removal with both analyzed types of salts had similar thermal denaturation characteristics. However, the fibers after PG removal with NaCl, in contrast to those obtained after MgCl2 treatment, showed different rheological properties during gelatinization and smaller diameter size. Moreover, the degree of fibrillogenesis of collagens after NaCl treatment was complete compared to that with MgCl2, which was only partial (70%). The structures of fibers after lyophilization were fundamentally different. The matrices obtained after NaCl pretreatment form regular scaffolds in contrast to the thin, surface structures of the cartilage matrix after proteoglycans removal using MgCl2.

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“…Collagen molecules become more positively charged in acidic environments, and this positive charge helps their solubilization by producing repulsion among tropocollagen molecules. [17] Organic acids, including i) acetic acid (CH3COOH) [20,21], ii) citric acid (C6H8O7) [22], iii) tartaric acid (C4H6O6) and iv) chloroacetic acid and inorganic acids such as i) hydrochloric acid (HCl) and ii) formic acid (CH2O2), are used for the isolation of collagen. [4] Organic acids, on the other hand, are more successful than inorganic acids at cleaving the crosslinks of collagen molecules, resulting in better collagen extractability.…”

Section: Chemical Hydrolysismentioning

confidence: 99%

Collagen Biopolymer in Textile Wet Processing

Hassabo

Othman

Bakr

et al. 2022

J.Text.color. pol. sci.

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C ollagen is the most abundant protein in the animal kingdom and is a key component of the extracellular matrix (ECM). Collagen is produced from both natural and synthetic resources. Natural resources are the best resources. Collagen has attracted wide attention in several fields due to its abundance, low cost, and exciting physical and chemical properties, especially, biocompatibility and biodegradability. However, collagen suffers from weak physical and chemical characteristics (mechanical strength, thermostability and resistance to enzyme). As a result, collagen must be modified throughout the processing process. collagen is an ecofriendly resource that can be used to produce multifunctional, recyclable, biocompatible, and biodegradable materials that are ideal for new technologies in materials science, biomedicine, and environmental remediation.

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Collagen production from chicken keel bone using acid and enzymatic treatment at a temperature of 30 °C

Cited by 10 publications

References 24 publications

Functional properties and antioxidant activity of gelatine and hydrolysate from deer antler base

Functional properties and antioxidant activity of gelatine and hydrolysate from deer antler base

Characteristics of Reconstituted Collagen Fibers from Chicken Keel Cartilage Depends on Salt Type for Removal of Proteoglycans

Collagen Biopolymer in Textile Wet Processing

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