利用转盘共聚焦显微镜进行快速实验的新方法

转盘共聚焦显微镜是快速激光共聚焦显微镜的一种,与传统的激光共聚焦显微镜相比具有一些相同点,也有其特有的优势。本文主要介绍转盘共聚焦显微镜的基本原理及如何利用转盘共聚焦显微镜进行快速实验及应用实例,并与传统激光共聚焦显微镜进行比较。转盘共聚焦显微镜具有速度快、灵敏度高、对样品光损伤和光淬灭程度低、操作灵活简单,是随着实验技术发展使用越来越广泛的实验仪器。     

三种显微技术对人毛囊蠕形螨的观察和研究

目的 采用荧光显微镜、扫描电镜和激光共聚焦显微镜对人体毛囊形蠕形螨进行形态学观察.方法 选用5 μg/mL碘化丙啶(propidine iodide,PI)对虫体进行荧光染色,避光染色15 min,分别置于荧光显微镜和激光共聚焦显微镜下观察;2.5%戊二醛固定虫体标本,梯度酒精和叔丁醇脱水,金喷镀后扫描电镜观察.结果 荧光显微镜下碘化丙啶对虫体有很强的结合力,虫体荧光信号均匀展示于细胞表面,充分展现虫体形态,扫描电镜更加清楚、细致地展示人体毛囊型蠕形螨的超微结构,激光共聚焦显微镜将虫体分层扫描图片进行三维重建,真实、完全、直观地展露了虫体.结论 三种显微技术均可展示蠕形螨超微形态.PI对虫体有很好的荧光染色作用,使激光扫描共聚焦显微镜能够获得更加精准的超微形态结构,结合三维重建技术有着广泛的应用价值.     

用激光共聚焦显微镜鉴别可疑笔迹与印章

本文采用激光共聚焦显微镜鉴别可疑笔迹和印章及其它的文件。法医在鉴别可疑文件时通常都是凭经验和用普通光学显微镜,找出其中的一些物理特征。但还是有许多文件的笔迹顺序无法确定,尤其是墨水写的笔迹,为解决法医的这一问题,我们用激光共聚焦显微镜鉴别了72例不同铅笔和圆珠笔写的肉眼难于鉴别的交叉笔顺和其他的一些文字文件。在激光共激光共聚焦显微镜下大多数笔迹和印章都能发出荧光,因此很容易鉴别其笔顺和印章的特征,必要时还可以进行笔顺的三维图象构建,以帮助鉴别。结论：激光共聚焦显微镜可以更准确地鉴别可疑笔迹和印章。印章和笔迹的交叉也很容易分辨出来。     

心肌细胞钙瞬变和细胞收缩的激光共聚焦成像研究

目的：游离钙离子参与机体的多种重要生理功能。本研究着重探讨如何利用激光共聚焦显微镜线扫描成像技术同时记录正常情况下心肌细胞的钙瞬变以及由此引起的细胞收缩过程。方法与结果：本研究以分离的心室肌细胞为对象,通过局部场刺激诱发细胞的钙瞬变和收缩,同时配合使用激光共聚焦显微镜成像系统,以线扫描方式记录实验结果。结果表明,钙瞬变先于细胞收缩发生(约早31ms),而收缩最大处远落后于钙瞬变峰值发生处(约慢346ms)。结论：激光共聚焦显微镜线扫描成像技术具有较好的时问分辨率和空间分辨率,其实验结果直观、明确、可靠,是较理想的研究钙瞬变和细胞收缩的光学记录方法。     

激光共聚焦扫描显微镜在抗菌机理研究中的应用

激光共聚焦扫描显微镜采用激光光源、共聚焦技术和点扫描技术,使其分辨力较传统光学显微镜大为提高。与其他的生物学技术相配合,可定性、定量、定位地检测组织细胞内的多种生化成分。它具有的活细胞动态监测、断层扫描及三维图像重建等功能,使其在抗菌机理研究、尤其是抗生物膜研究中得到大量的应用。本文就激光共聚焦扫描显微镜在抗菌剂作用位点,抗菌剂对微生物细胞膜,微生物生理代谢,以及微生物生物膜形成与结构的影响等研究中的应用做一综述。     

一种同步观察喜树碱与菌根丛枝结构的方法

本文介绍一种用激光共聚焦扫描显微镜同步观察喜树碱、丛枝茵根及其结构的方法.喜树丛枝茵根经甘油浸润和明胶包埋后制成切片,再经酸性品红染色后在激光共聚焦扫描显微镜下观察.波长488mm处激发光下可获得清晰的丛枝茵根透射图像.364 nm处激发光下可获得喜树碱的荧光图像,通过两图像的叠加,在喜树丛枝菌根中得到喜树碱的定位图像.用此方法初步研究了喜树丛枝茼根的喜树碱分布.     

激光共聚焦显微镜在肿瘤免疫治疗检测中的应用

目的:通过激光共聚焦显微镜对肿瘤生物治疗后患者的外周血淋巴细胞进行亚群计数,为生物治疗后外周血淋巴细胞无法分群的肿瘤患者提供新的监测免疫功能状态的方法。方法:收集35例肿瘤生物治疗后患者的外周血标本,通过激光共聚焦显微镜和流式细胞仪两种方法分别对患者外周血淋巴细胞亚群进行分类计数。结果:流式细胞仪和激光共聚焦显微镜同时分类计数的患者外周血细胞标本30例,两种方法在检测CD3、CD3~+/CD4~+、CD3~+/CD8~+、CD3-/CD16~+56~+、CD3-/CD19~+细胞时均无统计学差异(P值0.05);5例流式细胞仪无法将患者外周血淋巴细胞分群的样本,通过激光共聚焦显微镜可以进行分类计数。结论:激光共聚焦显微镜亦可以用于外周血淋巴细胞的分类计数。     

利用激光共聚焦扫描显微镜对溃疡病菌侵染柑橘叶片的实时观察

柑橘溃疡病对柑橘产业造成了巨大损失,而研究柑橘与溃疡病菌的互作关系以及柑橘的感病和抗病性均需要观察溃疡病菌在柑橘寄主中的侵染和定殖过程。激光共聚焦扫描显微镜不仅可以观察活细胞,活组织的动态代谢过程,而且可以获得三维图像,对于病原菌在柑橘植物组织内的繁殖和致病机制研究具有重要意义。但是,选择适宜的植物材料和制片方法对激光共聚焦扫描显微镜的观察效果影响很大。本文对激光共聚焦扫描显微镜所观察的材料在其处理和观察方法上加以改进,获得了质量更好的图片和实验结果,也使得实验更为方便快捷。激光共聚焦扫描显微观察还在瞬时表达分析中得到应用,提高了柑橘瞬时表达分析的效果。通过将切片和压片相结合观察到溃疡病菌在不同时间点对柑橘叶片的侵染情况,而通过3D建模能观察到柑橘叶片不同组织层面中的病菌数量和病菌位置,为研究溃疡病菌在叶片中的定殖方式和入侵数量提供了前期基础。     

成人外周血内皮祖细胞的分离、扩增及鉴定

目的: 从健康成人外周血中分离获取内皮祖细胞(endothelial progenitor cell ,EPC),并探索EPC体外扩增所需的条件.方法: 密度梯度离心法获取外周血单个核细胞,接种在人纤维连接蛋白包被培养板,用含VEGF的培养液培养7 d,收集贴壁细胞,激光共聚焦显微镜和流式细胞仪鉴定EPC.结果: 从成人外周血可分离获得EPC; 激光共聚焦显微镜可成功鉴定EPC;VEGF和人纤维连接蛋白对该细胞的生长有促进作用.结论: 外周血EPC的分离获取及其体外扩增条件的初步认识,为EPC的进一步研究及临床应用奠定了基础.     

角膜激光共聚焦显微镜在单眼感染性角膜炎疾病诊断中的应用

摘要 目的：探讨角膜激光共聚焦显微镜在单眼感染性角膜炎疾病诊断中的应用价值。方法：回顾性研究2020年6月到2021年6月选择在本院诊治的单眼感染性角膜炎疾病患者62例,所有患者都给予角膜激光共聚焦显微镜检查,记录影像学特征并判断诊断价值（以病原学诊断为金标准）。结果：真菌性角膜炎在角膜激光共焦显微镜下的病变区纵横交错的高反射的真菌菌丝或高反光细长颗粒状的孢子,细菌性角膜炎的病变处会聚集活化的树突状细胞及大量的炎症细胞,病毒性角膜炎的基底膜下神经纤维密度、神经主干的分支数减少,棘阿米巴性角膜炎的包囊表现为圆形高反光厚壁结构。角膜激光共聚焦显微镜判断为病毒性角膜炎17例,诊断病毒性角膜炎的敏感性与特异性为94.4 %和100.0 %;角膜激光共聚焦显微镜判断为棘阿米巴性角膜炎4例,诊断棘阿米巴性角膜炎的敏感性与特异性为94.4 %和100.0 %;角膜激光共聚焦显微镜判断为细菌性角膜炎21例,诊断细菌性角膜炎的敏感性与特异性为95.5 %和97.5 %;角膜激光共聚焦显微镜判断为真菌性角膜炎20例,诊断真菌性角膜炎的敏感性与特异性为94.4 %和93.2 %。ROC曲线分析显示角膜激光共聚焦显微镜诊断细菌性角膜炎、真菌性角膜炎、病毒性角膜炎、棘阿米巴性角膜炎的曲线下面积分别为0.525、0.579、0.777、0.731。结论：角膜激光共聚焦显微镜在单眼感染性角膜炎疾病诊断中的应用能较好的区分细菌性角膜炎、真菌性角膜炎、病毒性角膜炎、棘阿米巴性角膜炎,具有良好的诊断敏感性与特异性。     

Histological Observations of Dental Tissues Using the Confocal Laser Scanning Microscope

To investigate the time course of mineralization in undecalcified dental tissues, calcein-and tetracycline-labeled rat maxillary molar sections were stained with Villanueva bone stain en bloc, embedded in methyl-methacrylate (MMA), ground to 50 μm thickness, and observed by confocal laser scanning microscopy (CLSM). This method allowed observation of dental structures including odontoblasts, pulp cells and periodontal ligament, and dentinal tubules and enamel rods at high resolution; labeled enamel, dentine, and cementum could be observed simultaneously regardless of section thickness. CLSM permitted simultaneous observation of both the components of calcified tissue and the cellular components of dental tissues, and assessment of the mineralization time course of hard tissues labeled by tetracycline or calcein. The technique is useful for both assessing the elements composing dental structure and observing the histological dynamics by which dental structure develops.     

Three‐dimensional cellular imaging in thick biological tissue with confocal detection of one‐photon fluorescence in the near‐infrared II window

Fluorescence imaging in the second near‐infrared optical window (NIR‐II, 900‐1700 nm) has become a technique of choice for noninvasive in vivo imaging in recent years. Greater penetration depths with high spatial resolution and low background can be achieved with this NIR‐II window, owing to low autofluorescence within this optical range and reduced scattering of long wavelength photons. Here, we present a novel design of confocal laser scanning microscope tailored for imaging in the NIR‐II window. We showcase the outstanding penetration depth of our confocal setup with a series of imaging experiments. HeLa cells labeled with PbS quantum dots with a peak emission wavelength of 1276 nm can be visualized through a 3.5‐mm‐thick layer of scattering medium, which is a 0.8% Lipofundin solution. A commercially available organic dye IR‐1061 (emission peak at 1132 nm), in its native form, is used for the first time, as a NIR‐II fluorescence label in cellular imaging. Our confocal setup is capable of capturing optically sectioned images of IR‐1061 labeled chondrocytes in fixed animal cartilage at a depth up to 800 μm, with a superb spatial resolution of around 2 μm.      

用激光共聚焦扫描技术研究昆虫触角叶的雌雄异构性

【目的】本研究探讨用激光共聚焦扫描显微镜对昆虫触角叶内结构的扫描技术。【方法】选取鳞翅目斜纹夜蛾Spodoptera litura, 蜚蠊目美洲大蠊Periplaneta americana和鞘翅目松墨天牛Monochamus alternatus, 仔细解剖得到昆虫完整脑组织, 经过Lucifer yellow染色、戊二醛固定、梯度酒精脱水和透明等一系列处理后, 用激光共聚焦扫描显微镜对昆虫触角叶结构进行分层扫描。【结果】结果显示: 经该方法处理后在激发光488 nm下能清晰扫描出昆虫触角内典型结构神经纤维球, 并且可清晰看到这3种昆虫雄性触角叶结构内的扩大型神经纤维球复合体(macroglomerular complex, MGC), 而在相应雌性昆虫体内都没有此复合体。另外通过5 μm分层扫描得到斜纹夜蛾、美洲大蠊和松墨天牛的触角叶平均厚度分别为130, 235和115 μm, 神经纤维球数量分别为35, 59和39个。【结论】激光共聚焦扫描技术是获得昆虫触角叶内部结构的一个可行方法。     

共聚焦激光扫描显微镜在发育生物学中的应用

共聚焦激光扫描显微镜以高空间分辨率、非介入无损伤性连续光学切片、实时动态观察等优越性,应用于生物医学众多领域中。本文主要论述共聚焦激光扫描显微镜在发育生物学中的应用。     

Histological Observations of Dental Tissues Using the Confocal Laser Scanning Microscope

To investigate the time course of mineralization in undecalcified dental tissues, calcein-and tetracycline-labeled rat maxillary molar sections were stained with Villanueva bone stain en bloc, embedded in methyl-methacrylate (MMA), ground to 50 μm thickness, and observed by confocal laser scanning microscopy (CLSM). This method allowed observation of dental structures including odontoblasts, pulp cells and periodontal ligament, and dentinal tubules and enamel rods at high resolution; labeled enamel, dentine, and cementum could be observed simultaneously regardless of section thickness. CLSM permitted simultaneous observation of both the components of calcified tissue and the cellular components of dental tissues, and assessment of the mineralization time course of hard tissues labeled by tetracycline or calcein. The technique is useful for both assessing the elements composing dental structure and observing the histological dynamics by which dental structure develops.     

激光共焦显微成像的最新进展及其在生命科学研究中的应用

激光扫描共聚焦显微镜近年来得到了迅速发展,是近代最先进的细胞生物医学分析仪器之一。通过它可以对观察样品进行无创断层扫描和成像,在生物学和医学研究诊断的各个方面都得到了广泛的应用。本文主要介绍了激光扫描共焦显微镜的基本原理和发展状况,并着重介绍了在共焦荧光显微镜中采用薄荧光层和切片成像特性图来表征成像状态的功能。这种方法一般用于表征共聚焦和多光子显微镜的成像特性,是比较显微镜切片成像条件、成像质量等相关性能的重要依据。     

共聚焦显微镜对蒸发过强型干眼眼表结构的观察

目的:干眼已成为影响人们生活质量的主要眼表疾病之一。有关干眼的研究已成为当今眼科的研究热点,本文通过激光共焦显微镜对蒸发过强型干眼患者眼表结构特征进行观察,从细胞层面对干眼进行研究。方法:海德堡激光共焦显微镜(HRT3)对35例(60只眼)干眼患者及35名(60只眼)正常人的角膜上皮层朗格汉斯细胞,睑板腺腺泡密度,睑板腺开口直径及形态进行观察,并对观察结果进行描述记录。结果:正常眼角膜中央上皮层朗格汉斯细胞(LC)个数的平均密度为58±19个/mm2,干眼组为(137±29)个/mm2,两者比较差异具有统计学意义(P0.05)。正常眼组角膜上皮下朗格汉斯细胞突起较短,分支较少,干眼患者角膜上皮下朗格汉斯细胞突起呈树支状,其突起较正常眼组数量多且长度较长,正常组睑板腺(MG)腺泡的平均密度为115±28个/mm2,干眼患者的睑板腺腺泡的平均密度59±16个/mm2,两者比较差异具有统计学意义(P0.05)。干眼组睑板腺腺泡内呈中等程度反光,对照组腺泡内呈低反光。正常组睑板腺开口呈圆形,内壁光滑,直径为62±14μm,干眼组睑板腺开口欠光滑,直径35±11μm,两者比较差异具有统计学意义(P0.05)。结论:共聚焦显微镜观察到在蒸发过强型干眼患者中,睑板腺腺泡直径增大,密度降低,睑板腺的开口直径变小,同时,角膜朗格汉斯细胞活化,数量增多,共聚焦显微镜可从细胞层面观察蒸发过强性干眼的眼表结构改变,使干眼病理变化的研究更为直观,为今后的进一步研究提供了更为准确的材料。     

A novel multisite confocal system for rapid Ca2+ imaging from submicron structures in brain slices

In brain slices, resolving fast Ca²⁺ fluorescence signals from submicron structures is typically achieved using 2‐photon or confocal scanning microscopy, an approach that limits the number of scanned points. The novel multiplexing confocal system presented here overcomes this limitation. This system is based on a fast spinning disk, a multimode diode laser and a novel high‐resolution CMOS camera. The spinning disk, running at 20 000 rpm, has custom‐designed spiral pattern that maximises light collection, while rejecting out‐of‐focus fluorescence to resolve signals from small neuronal compartments. Using a 60× objective, the camera permits acquisitions of tens of thousands of pixels at resolutions of ~250 nm per pixel in the kHz range with 14 bits of digital depth. The system can resolve physiological Ca²⁺ transients from submicron structures at 20 to 40 μm below the slice surface, using the low‐affinity Ca²⁺ indicator Oregon Green BAPTA‐5N. In particular, signals at 0.25 to 1.25 kHz were resolved in single trials, or through averages of a few recordings, from dendritic spines and small parent dendrites in cerebellar Purkinje neurons. Thanks to an unprecedented combination of temporal and spatial resolution with relatively simple implementation, it is expected that this system will be widely adopted for multisite monitoring of Ca²⁺ signals.      

激光扫描共聚焦显微镜在蛋白质晶体生长研究中的应用

激光扫描共聚焦显微镜与普通光学显微镜相比,其分辨率高,同时具有可对样品进行非侵入性无损伤断层扫描,以及对样品形貌进行三维成建等特点,因此,可作为研究晶体生长强有利的工具。本文介绍了其在定量测量晶体的个数,重组三维图像以获得晶体生长的过程信息及测定晶体生长台阶动态变化等方面的应用。还对激光扫描共聚焦显微镜在晶体生长研究的其它方面应用前景作了展望。     

Axially‐confined in vivo single‐cell labeling by primed conversion using blue and red lasers with conventional confocal microscopes

Green‐to‐red photoconvertible fluorescent proteins have been found to undergo efficient photoconversion by a new method termed primed conversion that uses dual wave‐length illumination with blue and red/near‐infrared light. By modifying a confocal laser‐scanning microscope (CLSM) such that two laser beams only meet at the focal plane, confined photoconversion at the axial dimension has been achieved. The necessity of this custom modification to the CLSM, however, has precluded the wide‐spread use of this method. Here, we investigated whether spatially‐restricted primed conversion could be achieved with CLSM without any hardware modification. We found that the primed conversion of Dendra2 using a conventional CLSM with two visible lasers (473 nm and 635 nm) and a high NA objective lens (NA, 1.30) resulted in dramatic restriction of photoconversion volume: half‐width half‐maximum for the axial dimension was below 5 μm, which is comparable to the outcome of the original method that used the microscope modification. As a proof of this method's effectiveness, we used this technique in living zebrafish embryos and succeeded in revealing the complex anatomy of individual neurons packed between neighboring cells. Because unmodified CLSMs are widely available, this method can be widely applicable for labeling cells with single‐cell resolution.