Monitoring glycation using the intrinsic fluorescence of biological fluorophores

Rhona Muir, S. Forbes, D. Birch, O. Rolinski
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Abstract

The high blood glucose levels associated with diabetes affect various cells and proteins in the body. In response to high blood glucose collagen and keratin proteins experience glycation. This work aims to establish if the intrinsic fluorescence of collagen and keratin could be used to monitor the glycation of said compounds, and thus offer an alternative method to monitoring long term glycaemic control. We have studied the evolution of the intrinsic fluorescence of both compounds in response to glucose in vitro, using steady state and time-resolved fluorescence spectroscopy techniques. Changes in the intrinsic fluorescence of both collagen and keratin were observed. For collagen, contrary to the traditional fluorescence intensity decay measurement at arbitrarily selected excitation and detection wavelengths, we conducted systematic wavelength- and time-resolved measurements to achieve time-resolved emission spectra (TRES). These showed changes in the intrinsic fluorescence kinetics, caused by both collagen aggregation and glycation. In keratin, the addition of glucose caused an increase in the fluorescence intensity at the characteristic wavelength of 460 nm, due to faster formation of new cross-links. The results also suggest that glucose may cause the formation of two new fluorescent complexes with peak fluorescence at ~525 nm and ~575 nm. In conclusion, monitoring the intrinsic fluorescence of collagen or keratin could be used as a method to monitor long term glycaemic control in patients with diabetes.
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利用生物荧光团的固有荧光监测糖基化
与糖尿病相关的高血糖水平会影响体内的各种细胞和蛋白质。在高血糖反应中,胶原蛋白和角蛋白发生糖基化。这项工作旨在确定胶原蛋白和角蛋白的固有荧光是否可以用于监测所述化合物的糖基化,从而提供一种监测长期血糖控制的替代方法。我们利用稳态和时间分辨荧光光谱技术研究了这两种化合物在体外对葡萄糖的响应中固有荧光的演变。观察到胶原蛋白和角蛋白固有荧光的变化。对于胶原蛋白,与传统的任意选择激发和检测波长的荧光强度衰减测量不同,我们进行了系统的波长和时间分辨测量,以获得时间分辨发射光谱(TRES)。这些显示了内在荧光动力学的变化,由胶原聚集和糖基化引起。在角蛋白中,葡萄糖的加入使得在460 nm特征波长处的荧光强度增加,这是由于新的交联更快地形成。结果还表明,葡萄糖可能在~525 nm和~575 nm处形成两个新的荧光配合物。综上所述,监测胶原或角蛋白的固有荧光可作为监测糖尿病患者长期血糖控制的一种方法。
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