Carlos A. Renteria , Jaena Park , Chi Zhang , Janet E. Sorrells , Rishyashring R. Iyer , Kayvan F. Tehrani , Alejandro De la Cadena , Stephen A. Boppart
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We evaluate two- and three-photon excited autofluorescence, and second and third harmonic generation to determine meaningful intrinsic contrast mechanisms in brain tissue using simultaneous label-free, autofluorescence multi-harmonic (SLAM) microscopy.</p></div><div><h3>Results</h3><p>Regional differences quantified in the cortex, caudate, and thalamus of the brain demonstrate region-specific changes to metabolic profiles measured from FAD intensity, along with brain-wide quantification. While the overall intensity of FAD signal significantly decreased after morphine incubation, this metabolic molecule accumulated near the nucleus accumbens.</p></div><div><h3>Comparison with existing methods</h3><p>Histopathology requires tissue fixation and staining to determine cell type and morphology, lacking information about cellular metabolism. Tools such as fMRI or PET imaging have been widely used, but lack cellular resolution. 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We evaluate two- and three-photon excited autofluorescence, and second and third harmonic generation to determine meaningful intrinsic contrast mechanisms in brain tissue using simultaneous label-free, autofluorescence multi-harmonic (SLAM) microscopy.</p></div><div><h3>Results</h3><p>Regional differences quantified in the cortex, caudate, and thalamus of the brain demonstrate region-specific changes to metabolic profiles measured from FAD intensity, along with brain-wide quantification. While the overall intensity of FAD signal significantly decreased after morphine incubation, this metabolic molecule accumulated near the nucleus accumbens.</p></div><div><h3>Comparison with existing methods</h3><p>Histopathology requires tissue fixation and staining to determine cell type and morphology, lacking information about cellular metabolism. Tools such as fMRI or PET imaging have been widely used, but lack cellular resolution. 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引用次数: 0
摘要
背景:尽管吗啡等阿片类药物对神经激活和葡萄糖消耗的影响已众所周知,但使用和滥用阿片类药物的代谢机制尚未得到充分探索。多光子显微镜(MPM)技术是为高空间分辨率光学成像而开发的。尽管神经成像中使用的多光子显微镜越来越多,但内在光学对比在神经科学中的应用却少之又少:新方法:我们提出了一种无标记、多模态显微镜技术,用于分析小鼠脑组织在硫酸吗啡(MSO4)培养后的代谢情况。我们评估了双光子和三光子激发的自发荧光以及二次谐波和三次谐波的产生,利用同步无标记自发荧光多谐波(SLAM)显微镜确定脑组织中有意义的内在对比机制:结果:在大脑皮层、尾状核和丘脑中量化的区域差异表明,根据 FAD 强度和全脑量化测量的新陈代谢特征发生了特定区域的变化。与现有方法的比较:组织病理学需要通过组织固定和染色来确定细胞类型和形态,缺乏有关细胞代谢的信息。fMRI或PET成像等工具已被广泛使用,但缺乏细胞分辨率。SLAM显微镜无需进行组织制备,可立即使用并在原生环境中对组织进行亚细胞分辨率成像:本研究证明了 SLAM 显微镜在神经代谢无标记研究中的实用性,尤其是 FAD 自发荧光的强度变化和三次谐波产生的结构形态。
Large field-of-view metabolic profiling of murine brain tissue following morphine incubation using label-free multiphoton microscopy
Background
Although the effects on neural activation and glucose consumption caused by opiates such as morphine are known, the metabolic machinery underlying opioid use and misuse is not fully explored. Multiphoton microscopy (MPM) techniques have been developed for optical imaging at high spatial resolution. Despite the increased use of MPM for neural imaging, the use of intrinsic optical contrast has seen minimal use in neuroscience.
New Method
We present a label-free, multimodal microscopy technique for metabolic profiling of murine brain tissue following incubation with morphine sulfate (MSO4). We evaluate two- and three-photon excited autofluorescence, and second and third harmonic generation to determine meaningful intrinsic contrast mechanisms in brain tissue using simultaneous label-free, autofluorescence multi-harmonic (SLAM) microscopy.
Results
Regional differences quantified in the cortex, caudate, and thalamus of the brain demonstrate region-specific changes to metabolic profiles measured from FAD intensity, along with brain-wide quantification. While the overall intensity of FAD signal significantly decreased after morphine incubation, this metabolic molecule accumulated near the nucleus accumbens.
Comparison with existing methods
Histopathology requires tissue fixation and staining to determine cell type and morphology, lacking information about cellular metabolism. Tools such as fMRI or PET imaging have been widely used, but lack cellular resolution. SLAM microscopy obviates the need for tissue preparation, permitting immediate use and imaging of tissue with subcellular resolution in its native environment.
Conclusions
This study demonstrates the utility of SLAM microscopy for label-free investigations of neural metabolism, especially the intensity changes in FAD autofluorescence and structural morphology from third-harmonic generation.
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