Your search keyword '"Yan, Jia‐Nan"' showing total 2 results

1. Storage stability of scallop (Patinopecten yessoensis) male gonad hydrolysates/κ-carrageenan composite hydrogels embeded curcumin.

Author

Yan, Jia-Nan, Jiang, Xin-Yu, Li, Lin, Sun, Wen, Lai, Bin, and Wu, Hai-Tao

Subjects

*CURCUMIN, *GONADS, *SCALLOPS, *HYDROGELS, *CARRAGEENANS, *WATER distribution, *PROTEIN hydrolysates

Abstract

The combination of scallop male gonads hydrolysates (SMGHs) and κ -carrageenan (KC) was applied for curcumin (Cur) embedment and preservation, the corresponding Cur retention rate as well as gelation and microstructural properties were investigated during storage subjected to various pH (8 and 6) and temperature (25 °C and 4 °C). SMGHs-based gels could well protect Cur from degradation during 4 °C storage, with retention rate ranging from 95% to 97% after 30 day storage. At 25 °C, Cur could still be well preserved in SMGHs-based gels under pH 6 with Cur retention rate above 90%, while pH 8 led to rapid Cur degradation to around 75%. In addition, at pH 8 and 25 °C, the gel strength of SMGHs-Cur deteriorated significantly while evidently enhanced in SMGHs/KC-Cur due to synergistic combination within SMGHs and KC in couple with dehydration effect. Moreover, the water migration and distribution of SMGHs-based Cur-loaded vehicles were relatively stable at 4 °C while revealed apparent deterioration at 25 °C during storage. Furthermore, the microstructures of SMGHs/KC-Cur gradually transformed from homogeneous network with dense and smooth pores to tattered network with large and fragmentary pores, especially at 25 °C, promoting more Cur degradation. This study demonstrated that SMGHs/KC-Cur exhibited better than SMGHs-Cur in Cur preservation, potentially performing as excellent and sustainable protein hydrolysate/polysaccharide soft materials in food and biomedical fields. [Display omitted] • Acidic and low temperature are favorable for Cur protection in SMGHs-based vehicles. • SMGHs/KC performs better Cur preservation than SMGHs above 98% at 4 °C after 30 day. • Enhanced gel strength of SMGHs/KC-Cur after pH 8, 4 °C storage is due to dehydration. • Water migration and distribution are stable at 4 °C while deteriorate at 25 °C. • Compact and dense porous networks of SMGHs/KC allow more Cur retention at 4 °C. [ABSTRACT FROM AUTHOR]

Published

2023

2. Influence of pH and blend ratios on the complex coacervation and synergistic enhancement in composite hydrogels from scallop (patinopecten yessoensis) protein hydrolysates and κ-carrageenan/xanthan gum.

Author

Yan, Jia-Nan, Xue, Shan, Du, Yi-Nan, Wang, Yu-Qiao, Xu, Shi-Qi, and Wu, Hai-Tao

Subjects

*XANTHAN gum, *CARRAGEENANS, *PROTEIN hydrolysates, *COACERVATION, *SCALLOPS, *HYDROGELS, *PHASE diagrams

Abstract

The purpose of this study was to characterize the electrostatic complexation between scallop Patinopecten yessoensis male gonad hydrolysates (SMGHs) and κ -carrageenan/xanthan gum (KC/XG) within pH 12–1 at different hydrolysate/polysaccharide ratios (9:1–1:9) and to investigate the influence of pH and ratios on gelation and microstructural properties for widening the application of marine-derived source. According to the phase diagram of SMGHs/KC/XG, pH c hold a constant value around pH 8.5, pH φ1 gradually shifted from 4.2 to 2.8, and pH max fluctuated within 2.4-1.4 as ratios decreasing from 9:1–2:8. Additionally, SMGHs/KC/XG showed higher gel strength in acid condition, as decreasing pH promoted the electrostatic attractive interactions within positively charged patches in SMGHs and negatively charged sulfate and carboxyl groups in KC/XG causing more tightly packed structures formation. Moreover, decreasing ratios from 9:1 to 3:7 could further enhance the gel strength of SMGHs/KC/XG, ascribing to the stronger gelation ability of polysaccharides and enough neutralization. Moreover, SMGHs/KC/XG exhibited well-organized microstructures with smaller pore sizes, denser and more homogeneous networks at more acid domains, supporting stronger gel strength. Therefore, this study provides theoretical and methodological basis for designing novel SMGHs/KC/XG hydrogels with considerable gel strength and microstructures through understanding the complex coacervation at different pH and ratios. • pH and ratio largely regulate turbidity changes of SMGHs/KC/XG complexes. • pH c exhibits ratio-independent, and pH φ1 , pH max exhibit ratio-dependent behaviors. • Higher KC/XG proportion supports stronger gel strength in soluble phases. • More SMGHs/KC/XG neutralization promotes gel formation in insoluble coacervate phase. • SMGHs/KC/XG exhibits well-organized and compact networks at acid condition. [ABSTRACT FROM AUTHOR]

Published

2022