阿达玛变换光谱和成像技术的应用和研究进展

阿达玛变换(HT)作为一种多通道光谱调制技术，具有多通道同时检测能力、多通道成像能力以及适用于数据处理等优点。综述了近十年来HT光谱和成像技术在分析科学中的应用和研究进展。主要从HT模板编码技术和HT激发序列应用技术等方面讨论了其最新发展和存在的问题，并展望了其发展前景。     

高分辨阿达玛变换显微荧光图像分析(Ⅰ)——系统的成像能力及其在单个肿瘤细胞分析中的应用

阿达玛变换(Hadamard transform, HT)是一种类似于傅里叶变换的光谱调制技术, 具有多通道同时检测和多通道成像能力. 实现高分辨HT成像的关键在于阿达玛模板的制作, 阿达玛模板有两种, 即移动式机械编码模板(Movable mechanical mask)和固定式光电模板(Stationary electro-optic mask). 在实际成像方面, 移动模板和固定模板各有优缺点: 前者一般用石英玻璃制作, 对光信号不会因模板吸收而导致信号损失, 因此数据很可靠, 而且模板的制作也较为容易, 但由于采用步进电机驱动而容易导致机械故障, 难以实现快速编码; 后者无移动部件, 无机械故障, 因此系统比较紧凑, 但由于它是由液晶材料制成的(可导致信号损失), 从而限制了其在某些光谱区域的使用. 此外, 它对系统的软件设计要求比前者高, 实现高分辨成像更加困难. 正是由于上述原因, 实现快速、高分辨HT成像具有一定难度, 最近有关HT成像技术的报道极少.     

高分辨阿达玛变换显微光谱成像系统研究

阿达玛变换(HT)是一种多通道的光谱调制技术,基于这一原理,研制了一种显微光谱成像系统.通过光学设计,除可以获得微小试样(如单个细胞)的光谱以外,还可以对试样进行分光谱成像,得到分辨率为256×256像素的256级灰度图像.通过对两种不同荧光发射波长的CdSe/ZnS量子点进行的分光谱成像测试表明,本系统具有良好的分光谱成像能力,可以对具有复杂光谱的物质针对其某一特定成分进行成像.     

阿达玛变换显微荧光成像在单细胞定量分析中的应用研究

本文探讨了用阿达玛变换（HT）显微荧光成像系统获得基于256灰度级图像的单细胞荧光强度和解码定标值之间的关系,将归一化的HT图像用于定量分析,建立了适合不同样品的定量分析方法.在此条件下,定量分析数据有很好的准确度和精密度;将系统用于单个乳腺肿瘤细胞的DNA定量分析,对乳腺肿瘤的良恶性及癌变程度进行判断,分析结果与病理学诊断结论一致.     

高分辨阿达玛变换显微荧光图像分析(Ⅱ)单细胞DNA荧光图像生成、处理及自动定量分析研究

本研究把荧光显微镜，阿达玛变换多通道成像技术和计算机图象处理技术结合起来，建立了一种单细胞DNA荧光图像自动定量分析系统，对系统的成像原理、信号编码和解码方法及单细胞定量分析方法进行了讨论，分析结果表明，本系统提供的单细胞定量分析数据稳定可靠。     

钩藤生物碱中一对异构体的TLC-FT-SERS研究

傅立叶变换表面增强喇曼光谱（FT－SERS）可高灵敏度检测单一组分的分子结构住处,金、银等金属的米粒子具有表面增强活性^[1],薄层色谱（TLC）可将微量混合物有效分离但不具备指纹检测功能,若将TLC与FT－SERS技术联用,则可使天然药物等提取得到高灵敏度分离与特征光谱检测,这项研究在国内外仅有补步报道^[2~5],钩藤为常用中草药,其有效成分生物碱具有改善心脑血液循环和脑功能的作用及清除自由基抗衰老活性,本文应用TLC－FT－SERS技术对天然药物钩藤中的生物碱进行高灵敏度的分析和特征喇曼光检测,在硅胶色谱板的钩藤碱与异钩藤碱与钩藤碱班点原位分别滴淋灰银胶,直接测得FT－SERS光谱。     

微流控进样阿达玛变换显微荧光成像单细胞分析

将微流控芯片用于单细胞进样,以自制阿达玛变换显微荧光成像分析系统进行成像检测,讨论了影响单细胞进样和荧光成像的主要因素,并对花粉细胞DNA含量进行定量分析。结果表明：微流控进样技术与HT显微成像技术相结合,可有效可靠地应用于单细胞分析中,所测定的三个玉帘花粉的DNA含量分别为124．4、123．9和62．9pg。     

高分辨阿达玛变换显微荧光图像分析(Ⅲ)——系统分辨率和图像恢复过程对单细胞分析结果的影响

提出了一种改进的阿达玛变换(HT)显微荧光图像分析系统,以单细胞试样分析为基础,分别对系统的分辨率和解码后的图像恢复过程进行了讨论.结果表明,该系统可应用于单细胞形态分析和定量分析.图像在x和y方向的像素分辨率相同,并达到了同一成像物镜下的空间分辨率水平,因此在获取微米级单细胞试样的微弱荧光信号的二维图像时,系统的成像能力较好,可用于单细胞形态分析.对花粉细胞的荧光衰退过程的定量分析结果表明,对不同HT图像提供的同一系列试样的定量数据进行比较时,必须对所有该系列试样的图像恢复过程进行归一化处理.     

β－环糊精与碳酸钙结晶的相互作用

依据生物矿化的基本原理，以β－环糊精（β－CD）作为有机基质，采用仿生 的方法合成了具有独特形貌的文石型碳酸, 其中含有少量的β－环糊精。用X射线 粉末衍射（XRD）分析、扫描电子显微镜（SEM）、傅里叶变换红外吸收光谱（FT－ IR）和电导率测定等手段对所得复合碳酸钙进行了表征，结果发现CaCO3结晶过程 中，β－环糊精与CaCO3之间存在着相互作用，并讨论了这种作用的可能机理。     

聚甘油脂肪酸酯的结构鉴定

该文采用傅里叶变换离子回旋共振质谱（FT－ICR－MS）、核磁共振氢谱（1H NMR）以及气相色谱－质谱（GC－MS）技术,对聚甘油脂肪酸酯的结构进行鉴定。样品溶解后进行FT－ICR－MS测定,根据精确分子离子数据,推测出聚甘油脂肪酸酯的基本结构以及甘油的聚合度,并采用1H NMR进行了验证。将聚甘油脂肪酸酯水解后,对脂肪酸部分进行甲酯化,经正庚烷萃取,由GC－MS测定,分析脂肪酸的组成。综合以上结果最终确定了聚甘油脂肪酸酯的结构。该研究为聚合物的结构鉴定提供了一种新的思路和方法。     

Hadamard transform fluorescence image microscopy using one-dimensional movable mask

With a 511-slit one-dimensional (1D) Hadamard mask and a highly sensitive linear charge-coupled device (CCD), spatial multiplexing is performed and a programmable Hadamard transform (HT) microscopic fluorescence imaging system was developed. The system can generate 511×512 pixel format images for small samples. Sensitivity, signal to noise ratio, imaging speed and spatial resolution of this system were discussed. The results show that the system can be applied for single-cell imaging sensitively in a short time. Spatial resolution up to 0.24 μm/pixel, which is close to the resolution limit of the conventional optical microscope, has been obtained under oil lens. The weak native fluorescence imaging for pollen cells can be realized within 1 min. The system has been applied for multi-parameter evaluation of tumor malignancy based on nuclear DNA ploidy measurements for one breast tumor specimen. The result indicates that the system has good application prospect in cell biology and medicine.     

High-resolution Hadamard transform microscope fluorescence imaging: quantifying the DNA content in single cells

This study presents a novel miniaturized Hadamard transform fluorescence imaging microscope, by combining a conventional fluorescence microscope with Hadamard transform multiplexing encoding using a one-dimensional movable mask to realize spatial resolution and a linear CCD for multichannel detection. The microscope can provide high-resolution automatically-generated 0–255 gray level HT images for morphological analysis and visualization of a single cell, and normalized HT images for cellular quantitative measurements. The microscopes imaging capability was applied to measure the DNA content in human lymphocyte, chicken erythrocyte and eel erythrocyte, and a comparative study was performed. The results show that the calibrated DNA content in a chicken erythrocyte is 2.32 pg when human lymphocyte is used as the standard, and eel erythrocyte may be a potentially reliable and novel standard for determining DNA contents in other species because it has a stable DNA value of 2.06 pg, with a CV of 4.3% when 20 eel erythrocytes are measured. The results also demonstrate that the HT imaging microscope should be valuable in the fields of medicine and cell biology.     

Quantitative DNA imaging in breast tumor cells by a Hadamard transform fluorescence imaging microscope.

This paper presents a novel Hadamard transform (HT) fluorescence imaging microscope by combining multiplexed imaging technique with a conventional upright fluorescence microscope for single-cell imaging and quantitative cellular analysis. The HT imaging microscope can provide 511 x 512-pixel single-cell image with high sensitivity within 21 s. In this study, the high potential value of the microscope in biomedical analysis has been demonstrated by using it to evaluate the malignancy degree of thirty cases of human breast tumors based on the measurements of cellular DNA contents, with conclusions highly accordant with pathological diagnosis. The results show that the HT microscope has the ability to analyze very small specimens and the capability of detecting very high ploidy cells, which are advantages over flow cytometry. The microscope was also successfully applied to cellular morphological analysis, and it was demonstrated that a significant linear relationship exists between tumor nuclear DNA contents and the nuclear area, and malignant and benign tumors are significantly different in both DNA contents and nuclear area. The reliability of the HT microscope in cellular DNA measurements was also investigated.     

多种超分辨荧光成像技术比较和进展评述

所见即所得是生命科学研究的中心哲学,贯穿在不断认识单个分子、分子复合体、分子动态行为和整个分子网络的历程中。活的动态的分子才是有功能的,这决定了荧光显微成像在生命科学研究中成为不可替代的工具。但是当荧光成像聚焦到分子水平的时候,所见并不能给出想要得到的。这个障碍是由于受光学衍射极限的限制,荧光显微镜无法在衍射受限的空间内分辨出目标物。超分辨荧光成像技术突破衍射极限的限制,在纳米尺度至单分子水平可视化生物分子,以前所未有的时空分辨率研究活细胞结构和动态过程,已成为生命科学研究的有力工具,并逐渐应用到材料科学、催化反应过程和光刻等领域。超分辨成像技术原理不同,其具有的技术性能各异,限制了各自特定的技术特色和应用范围。目前主流的超分辨成像技术包括3种:结构光照明显微镜技术(structured illumination microscopy, SIM)、受激发射损耗显微技术(stimulated emission depletion, STED)和单分子定位成像技术(single molecule localization microscopy, SMLM)。这些显微镜采用不同的复杂技术,但是策略却是相同和简单的,即通过牺牲时间分辨率来提升衍射受限的空间内相邻两个发光点的空间分辨。该文通过对这3种技术的原理比较和在生物研究中的应用进展介绍,明确了不同超分辨成像技术的技术优势和适用的应用方向,以方便研究者在未来研究中做合理的选择。     

A new sample substrate for imaging and correlating organic and trace metal composition in biological cells and tissues

Many disease processes involve alterations in the chemical makeup of tissue. Synchrotron-based infrared (IR) and X-ray fluorescence (XRF) microscopes are becoming increasingly popular tools for imaging the organic and trace metal compositions of biological materials, respectively, without the need for extrinsic labels or stains. Fourier transform infrared microspectroscopy (FTIRM) provides chemical information on the organic components of a material at a diffraction-limited spatial resolution of 2–10 μm in the mid-infrared region. The synchrotron X-ray fluorescence (SXRF) microprobe is a complementary technique used to probe trace element content in the same systems with a similar spatial resolution. However to be most beneficial, it is important to combine the results from both imaging techniques on a single sample, which requires precise overlap of the IR and X-ray images. In this work, we have developed a sample substrate containing a gold grid pattern on its surface, which can be imaged with both the IR and X-ray microscopes. The substrate consists of a low trace element glass slide that has a gold grid patterned on its surface, where the major and minor parts of the grid contain 25 and 12 nm gold, respectively. This grid pattern can be imaged with the IR microscope because the reflectivity of gold differs as a function of thickness. The pattern can also be imaged with the SXRF microprobe because the Au fluorescence intensity changes with gold thickness. The tissue sample is placed on top of the patterned substrate. The grid pattern’s IR reflectivity image and the gold SXRF image are used as fiducial markers for spatially overlapping the IR and SXRF images from the tissue. Results show that IR and X-ray images can be correlated precisely, with a spatial resolution of less than one pixel (i.e., 2–3 microns). The development of this new tool will be presented along with applications to paraffin-embedded metalloprotein crystals, Alzheimer’s disease, and hair composition.     

用于小动物活体的荧光-光热双模成像系统

报道了一种小动物活体荧光-光热双模成像系统, 其兼具荧光成像和热成像双功能, 具有成像灵敏度高、 采集速度快(≤51 frame/s)、 组织穿透深度大(近红外荧光成像时可达10 mm)以及0.1 ℃的热成像分辨率. 该系统不但能够实现小动物皮下肿瘤和深层组织/器官的荧光成像, 同时集成了热成像, 可实时监测光热治疗中的温度变化以及药物的控制释放过程, 有助于实现精准治疗.     

Infrared Matrix-Assisted Laser Desorption Electrospray Ionization (IR-MALDESI) Imaging Source Coupled to a FT-ICR Mass Spectrometer

Mass spectrometry imaging (MSI) allows for the direct monitoring of the abundance and spatial distribution of chemical compounds over the surface of a tissue sample. This technology has opened the field of mass spectrometry to numerous innovative applications over the past 15 years. First used with SIMS and MALDI MS that operate under vacuum, interest has grown for mass spectrometry ionization sources that allow for effective imaging but where the analysis can be performed at ambient pressure with minimal or no sample preparation. We introduce here a versatile source for MALDESI imaging analysis coupled to a hybrid LTQ-FT-ICR mass spectrometer. The imaging source offers single shot or multi-shot capability per pixel with full control over the laser repetition rate and mass spectrometer scanning cycle. Scanning rates can be as fast as 1 pixel/second and a spatial resolution of 45 μm was achieved with oversampling.

Fast,high resolution mass spectrometry imaging using a medipix pixelated detector

In mass spectrometry imaging, spatial resolution is pushed to its limits with the use of ion microscope mass spectrometric imaging systems. An ion microscope magnifies and then projects the original spatial distribution of ions from a sample surface onto a position-sensitive detector, while retaining time-of-flight mass separation capabilities. Here, a new type of position-sensitive detector based on a chevron microchannel plate stack in combination with a 512 × 512 complementary metal-oxide-semiconductor based pixel detector is coupled to an ion microscope. Spatial resolving power better than 6 μm is demonstrated by secondary ion mass spectrometry and 8–10μm spatial resolving power is achieved with laser desorption ionization. A detailed evaluation of key performance criteria such as spatial resolution, acquisition speed, and data handling is presented.