Multi-modal, Label-free, Optical Mapping of Cellular Metabolic Function and Oxidative Stress in 3D Engineered Brain Tissue Models

Yang Zhang, Maria Savvidou, Volha Liaudanskaya, Varshini Ramanathan, Thi Bui, Lindley Matthew, Ash Sze, Ugochukwu Obinna Ugwu, Fu Yuhang, Dilsizian E Matthew, Xinjie Chen, Sevara Nasritdinova, Aonkon Dey, Eric L Miller, David L Kaplan, Irene Georgakoudi
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Abstract

Brain metabolism is essential for the function of organisms. While established imaging methods provide valuable insights into brain metabolic function, they lack the resolution to capture important metabolic interactions and heterogeneity at the cellular level. Label-free, two-photon excited fluorescence imaging addresses this issue by enabling dynamic metabolic assessments at the single-cell level without manipulations. In this study, we demonstrate the impact of spectral imaging on the development of rigorous intensity and lifetime label-free imaging protocols to assess dynamically over time metabolic function in 3D engineered brain tissue models comprising human induced neural stem cells, astrocytes, and microglia. Specifically, we rely on multi-wavelength spectral imaging to identify the excitation/emission profiles of key cellular fluorophores within human brain cells, including NAD(P)H, LipDH, FAD, and lipofuscin. These enable development of methods to mitigate lipofuscin's overlap with NAD(P)H and flavin autofluorescence to extract reliable optical metabolic function metrics from images acquired at two excitation wavelengths over two emission bands. We present fluorescence intensity and lifetime metrics reporting on redox state, mitochondrial fragmentation, and NAD(P)H binding status in neuronal monoculture and triculture systems, to highlight the functional impact of metabolic interactions between different cell types. Our findings reveal significant metabolic differences between neurons and glial cells, shedding light on metabolic pathway utilization, including the glutathione pathway, OXPHOS, glycolysis, and fatty acid oxidation. Collectively, our studies establish a label-free, non-destructive approach to assess the metabolic function and interactions among different brain cell types relying on endogenous fluorescence and illustrate the complementary nature of information that is gained by combining intensity and lifetime-based images. Such methods can improve understanding of physiological brain function and dysfunction that occurs at the onset of cancers, traumatic injuries and neurodegenerative diseases.
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对三维工程脑组织模型中的细胞代谢功能和氧化应激进行多模式、无标记光学测绘
大脑新陈代谢对生物体的功能至关重要。虽然已有的成像方法能提供有关大脑代谢功能的宝贵见解,但它们缺乏捕捉细胞水平上重要代谢相互作用和异质性的分辨率。无标记双光子激发荧光成像技术无需操作即可在单细胞水平进行动态代谢评估,从而解决了这一问题。在本研究中,我们展示了光谱成像对制定严格的强度和寿命无标记成像方案的影响,以评估由人类诱导神经干细胞、星形胶质细胞和小胶质细胞组成的三维工程脑组织模型的动态代谢功能。具体来说,我们依靠多波长光谱成像来识别人脑细胞内关键细胞荧光团的激发/发射曲线,包括 NAD(P)H、LipDH、FAD 和脂褐素。通过这些方法,我们开发出了减轻脂褐素与 NAD(P)H 和黄素自发荧光重叠的方法,从而从两个激发波长和两个发射波段获得的图像中提取可靠的光学代谢功能指标。我们展示了在神经元单培养和三培养系统中报告氧化还原状态、线粒体碎片和 NAD(P)H 结合状态的荧光强度和寿命指标,以突出不同细胞类型之间代谢相互作用的功能影响。我们的研究结果揭示了神经元和神经胶质细胞在代谢方面的显著差异,揭示了代谢途径的利用情况,包括谷胱甘肽途径、OXPHOS、糖酵解和脂肪酸氧化。总之,我们的研究建立了一种无标记、非破坏性的方法,依靠内源性荧光评估不同脑细胞类型之间的代谢功能和相互作用,并说明了通过结合基于强度和寿命的图像所获得信息的互补性。这种方法可以提高人们对大脑生理功能以及癌症、外伤和神经退行性疾病发病时出现的功能障碍的认识。
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