رزومه وب سایت شخصی


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سیداحسان غیاثی

سیداحسان غیاثی

دانشیار

دانشکده: کشاورزی

گروه: علوم دامی

مقطع تحصیلی: دکترای تخصصی

سال تولد: ۱۳۶۳

رزومه وب سایت شخصی
EN
سیداحسان غیاثی

دانشیار سیداحسان غیاثی

دانشکده: کشاورزی - گروه: علوم دامی مقطع تحصیلی: دکترای تخصصی | سال تولد: ۱۳۶۳ |

My affiliation

گروه علوم دامی- دانشکده کشاورزی دانشگاه بیرجند - بیرجند - ایران

گروه پژوهشی تنش های محیطی در علوم دامی - دانشکده کشاورزی- دانشگاه بیرجند - بیرجند - ایران

نمایش بیشتر

Coordination of WPI Amyloid Fibrils/Hydrolysates with Zinc and Copper Ions: A Comparative Study on the Effect of Accompanying Anion

نویسندگانS.Ehsan Ghiasi,Rassul kadkhodaee,Mohsen Mojtahedi
نشریهFood Biophysics
شماره صفحات1-18
شماره سریال21
شماره مجلد79
ضریب تاثیر (IF)1.551
نوع مقالهFull Paper
تاریخ انتشار2026
رتبه نشریهISI
نوع نشریهالکترونیکی
کشور محل چاپایران
نمایه نشریهJCR،Scopus
کلید واژه هاWPI nanofibril · WPI hydrolysate · Metal coordination

چکیده مقاله

Metal-protein complexes are commonly used to supplement foods and feeds with essential minerals. This study investigated the coordination of Cu²⁺ and Zn²⁺ with WPI nanofibrils/hydrolysates, with a focus on the impact of the accompanying anion. The results showed that nanofibrils had a significantly higher binding ability compared to hydrolysates (50% versus 39%, respectively). Furthermore, Cu²⁺ exhibited a greater binding affinity towards proteins than Zn²⁺, with an approximately 25% higher binding efficiency. Among the accompanying anions, SO₄²⁻ was found to increase the coordination of metal ions more effectively than Cl⁻, achieving a binding efficiency of 50% compared to 37% for Cl⁻. Electrical conductivity measurements provided evidence of Cu²⁺ and Zn²⁺ binding to the proteins. UV–vis spectroscopy revealed that the metal-to-ligand charge transfer transition was the driving force behind the coordination reaction. The formation of metal-protein complexes was further supported by displacement and intensity changes of FTIR peaks, particularly the amide I, II, and III bands, as well as the N-H stretching vibration peak. SEM images visualized the binding of metal ions to the proteins, resulting in disruption of their original microstructure. SEM-coupled energy dispersive X-ray spectroscopy confirmed the presence of metal ions in the surface elemental composition of the chelates, which was also verified by the X-ray diffraction pattern spectra. These findings demonstrate the promising potential of nanofibrils to effectively coordinate metal ions.

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