基于多光谱荧光成像技术和SVM的葡萄霜霉病早期检测研究

葡萄霜霉病是全球危害最严重的葡萄病害,对该病进行早期检测和防治,可提高葡萄品质和产量,提出一种基于多光谱荧光成像技术(MFI)和支持向量机模型(SVM)的霜霉病早期检测方法。对人工接种霜霉病的葡萄叶片(145个)和健康对照叶片(145个)从叶背面连续6天进行多光谱荧光成像,获得试验叶片16个荧光参数(4个单独波段F440,F520,F690,F740及其相互比值)的图像。在分析不同荧光波段图像随接种天数(DPI)变化规律基础上,通过单因素方差分析和相关性分析,优选出进行霜霉病早期检测的4个波段特征F520,F690,F440/F740,F690/740,利用这4个特征构建基于SVM的霜霉病检测模型。试验发现,16个荧光参数都有早期检测霜霉病的潜力,四个单独波段中F440和F520比F690和F740对霜霉病的侵染更敏感,6DPI才显症的病斑能在F440和F520波段2DPI(接种后第二天)的荧光图像中凸显,接种叶片F440和F520波段荧光强度均随着DPI增加快速升高,在2DPI显著高于健康叶片(p<0.01),并随着DPI增加更加显著(p<0.0001);接种叶片F690和F740波段荧光强度均随着DPI增加逐渐减小,1DPI—3DPI与健康叶片无显著差异,从4DP I开始显著低于健康叶片(p<0.05),并在5DPI—6DPI更加显著(p<0.01);健康叶片荧光参数变化很小。F440极易受干扰,变异系数最大,F520最稳定。随着DPI增加,叶片被侵染程度加深,4个特征融合的SVM模型对健康和接种叶片检测准确率逐渐提高,1DPI的准确率为65.6%,3DPI检测准确率为82.2%,整个试验周期(1DPI—6DPI)的平均检测准确率达84.6%,高于单一特征中最优波段F520的阈值检测结果(1DPI的准确率为61.1%,3DPI检测准确率为78.9%,整个试验周期为80.0%)。结果表明利用MFI技术和SVM模型能实现霜霉病显症前的早期检测,为便携式葡萄霜霉病早期诊断设备的开发提供了理论依据。

用于实时微型多光谱荧光成像方法的二维点阵式多通道窄带滤镜

实时微型多光谱成像方法能够在零机械运动下,单次曝光同时获取目标对应于几个不同特征波段的多幅二维空间光谱图像,具有效率高、体积小、抗震等优点。具有高光密度值的二维点阵式窄带微滤片(简称微滤片)是用于活体荧光成像的实时微型多光谱荧光成像技术的核心部件。首先对微滤片进行优化设计及关键参数的确定,其次研制了既具有二维空间分辨、又有高光学密度值的微滤片。实测结果显示所研制微滤片基本周期单元具有52μm×52μm空间分辨率、透过带带宽为24 nm、光密度值高达4、不同光波段通道之间图像信号串扰微弱。该二维点阵式窄带微滤片的成功研制为实时微型多光谱荧光成像技术的应用扫清了障碍,对医疗活体光学病理诊断及使用多荧光探针来探索生命过程的研究有重要意义。

高温胁迫对两个杉木种源多光谱荧光和抗氧化酶的影响

本研究选择福建三明(FJSM)和江西九江(JXJJ)两地两年生的杉木种源作为试验材料,通过在人工气候箱内进行盆栽试验,研究了不同温度(25℃,30℃,35℃,40℃)对两个杉木种源的抗氧化酶活性和多光谱荧光的影响。结果表明:杉木的多光谱荧光参数F440、F520、F690、F740及其比值F690/F740随着高温胁迫的增加而升高。在高温胁迫下,FJSM的F690/F740的升高程度低于JXJJ。F690/F740的升高表明叶绿素含量的下降,FJSM种源在高温胁迫下叶绿素降解速度较慢,对高温的抗性更强。另外,经过高温胁迫后,杉木的SOD、POD和CAT等抗氧化酶活性总体上升。与JXJJ种源相比,FJSM在高温胁迫下抗氧化酶活性上升更大,下降趋势更小,表明FJSM更强的抗高温能力与抗氧化酶密切相关。

多光谱荧光影像的纯光谱分析与信号分离

多光谱活体荧光成像技术正逐渐成为生物医学研究的关键技术,但是荧光物质光谱之间的串扰和自发荧光现象严重影响了荧光影像的解译。混合光谱分解对于去除活体多光谱荧光影像自发荧光效应和进行多种荧光信号分离是非常有效的技术,但是光谱分解的前提是获得了各种荧光物质的光谱。基于多元曲线解析交替最小二乘法(MCR-ALS)计算框架,提出包括非负、等式、闭合性、单峰、波段范围及归一化的多约束条件的荧光纯光谱估计方法,利用估计的纯光谱和线性混合光谱模型得到不同荧光信号的分离,去除自发荧光背景对起标记目的的荧光物质信号的干扰。Dirichle分布随机混合构造的不同信噪比和纯净水平的荧光蛋白混合光谱数据分析结果反映出在混合问题严重、有噪声影响的情况下,该算法要比传统端元光谱分析方法的精度高10倍以上。活体鼠多光谱量子荧光影像的实验也证明了该算法在信号分离上的有效性。

乳腺癌分子分型用荧光分子影像探针

目前,乳腺癌的临床诊断就是结合病理类型和分子分型(免疫组化)。该方法是有创的,而且不能原位、实时地展现关键生物分子与临床关键信息之间的关系。本文介绍了利用分子影像技术对乳腺癌进行分子分型检测的最新研究进展。荧光成像灵敏度高,且不过分依赖图像分析,只需相应的荧光分子探针,即可实时、定量或半定量、多通道地得到肿瘤组织分子分型信息。因此,研制安全高效、组织穿透力强的近红外荧光分子探针是未来荧光成像技术和乳腺癌分子分型研究的重点。

时间分辨多光谱技术研究

本文讨论了具有时间分辨的多光谱探测技术 ,并通过结合钛宝石锁模激光器、荧光显微、高重复频率皮秒扫描相机等技术 ,研制出一套基于皮秒同步扫描相机的五维双光子激发荧光多参数复合显微成像系统 ,实现了细胞层次上的五维测量 ,并可方便地实现多种功能成像 ,例如荧光强度。

Applications of multiplexed immunohistochemistry/immunofluorescence and multispectral imaging technology in the field of tumor immunotherapy

Multiplexed immunohistochemistry/fluorescence(mIHC/IF)in combination with multispectral unmixing is a novel multitarget histopathological staining and imaging technique.By simultaneously revealing expression level and spatial information for up to eight biomarkers in situ,in addition to a nuclear stain within a single formalin-fixed paraffin-embedded(FFPE)tissue section,this technology can analyze the phenotype,abundance,morphology and intercellular relationship of cells while providing statistically significant results.In recent years,technical improvements have brought new insight into mIHC/IF and multispectral imaging approaches,which have been successfully applied in the field of cancer immunotherapy,specifically in regard to tumor microenvironment research,immunotherapy drug discovery,and prognostic and metastatic risk evaluation.This review highlights the principle,workflow,advantages and disadvantages of the technology,and discusses the latest applications of mIHC/IF-based imaging technology in the field of TME-related research and immunotherapy drug discovery.

Biophysical studies of the interaction between a triazole derivative and bovine serum albumin by multi-spectroscopic and molecular modeling methods

The interaction between 3-thiol-4-(2,4-dichlorobenzylideneamino)-5-methyl-4H-1,2,4-triazole (CBTZ) and bovine serum albumin (BSA) under physiological conditions was investigated by fluorescence,UV-vis absorption and circular dichroism (CD) spectroscopy as well as molecular modeling methods. The result of fluorescence experiment indicates the static quenching as a result of the formation of the CBTZ-BSA complex. The binding constants (Ka) at different temperatures were calculated according to the modified Stern-Volmer equation. The enthalpy change (-H) and entropy change (-S) were determined based on the van′t Hoff equation. Both negative-H and-S indicated that van der Waals and hydrogen-bonding forces were the dominant intermolecular forces to stabilize the CBTZ-BSA complex. Site marker competitive replacement experiments demonstrated that binding of CBTZ to BSA primarily took place in sub-domain IIA (Sudlow's site I). The binding distance (r = 7.2 nm) between CBTZ and the tryptophan residue of BSA was estimated according to the theory of fluorescence resonance energy transfer (FRET). The conformational studies by circular dichroism (CD) and three-dimensional fluorescence spectroscopy showed that the presence of CBTZ induced minor changes of the secondary structure of BSA. Molecular modeling study further confirmed the binding mode obtained experimentally.