合成和测试Zn(II)-Astaxanthin复合物

Winda Rahmalia, Dwi Imam Prayitno, Adhitiyawarman, Septiani
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引用次数: 0

摘要

虾青素是一种来自类胡萝卜素的色素,存在于藻类、虾和螃蟹中。由于其化学结构,虾青素有许多健康益处,但在直接暴露于光和氧下的稳定性较低。本研究采用回流反应器在37℃和60℃条件下合成了锌-虾青素配合物。用紫外-可见分光光度计和红外光谱对络合物进行分析。紫外-可见分光光度计分析显示丙酮的色移(475 ~ 477 nm)。相比之下,在二甲亚砜中,观察到493 ~ 475 nm的次色移,并在330 nm处观察到新的吸收峰。FTIR分析表明,在1712 cm-1和1219 cm-1处,C=O拉伸振动和-OH基团振动强度减小。这表明金属离子Zn2+与虾青素之间存在相互作用。在300 W/m2光强卤素灯照射6小时后,锌-虾青素在辐照过程中的稳定性优于虾青素。基于零级降解动力学模型,锌-虾青素配合物的降解速率常数为0.0621,小于虾青素的降解速率常数(0.0880)。
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Sintesis dan Uji Fotostabilitas Kompleks Zn(II)-Astaxanthin
Astaxanthin is a pigment from the carotenoid group found in algae, shrimp, and crabs. Due to its chemical structure, astaxanthin has many health benefits but low stability against direct exposure to light and oxygen. In this study, the Zn-astaxanthin complex was synthesized using a reflux reactor at 37o and 60oC. Complex compounds were analyzed using a UV-Vis spectrophotometer and FTIR. The UV-Vis spectrophotometer analysis showed a bathochromic shift in acetone (475 to 477 nm). In comparison, in dimethyl sulfoxide, a hypsochromic shift (493 to 475 nm) was observed, and a new absorption peak was observed at 330 nm. FTIR analysis shows a decrease in the intensity of the C=O stretching vibration and -OH group vibration at 1712 and 1219 cm-1, respectively. This indicated an interaction between the metal ion Zn2+ and astaxanthin. Zn-astaxanthin has better stability than astaxanthin during irradiation, using a halogen lamp at a light intensity of 300 W/m2 for 6 hours. Based on the zero-order degradation kinetics model, the degradation rate constant of the Zn-astaxanthin complex was 0.0621, smaller than that of astaxanthin (0.0880).
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