朴树种子和果实的生长发育

早在1964年,Leopold 就指出:果实生长的研究集中在园艺上重要植物的肉果上,对其它果实生长的研究报道很少。朴树(Celtis Sinensis)是榆科常见耐旱树种,迄今未见关于其果实、种子生长发育的报道。我们从盛花期开始,每两天一次,取其子房置FAA 中固定保存。用解剖镜、光学显微镜及扫描电镜观察了种子及果实的生长发育过程。用于光镜观察的材料采用常规石蜡切片法制片,爱氏苏木精整体染色,切片厚度8～10μm。用于扫描电镜观察的材料处理方法如前,成熟果实不经处理直接喷金观察。观察结果及讨论如下。     

树脂包埋半薄切片在视神经组织学和免疫组织化学研究中的应用

目的探讨半薄切片在视神经组织学和免疫组织化学研究中的应用,寻找一种视神经形态学研究和疾病诊断的有效方法。方法健康Sprague-Dawley大鼠视神经分别行树脂包埋制成半薄切片与石蜡包埋制成石蜡切片,分别采用HE、甲苯胺蓝染色及髓鞘碱性蛋白(myelin basic protein,MBP)免疫组织化学方法染色,光学显微镜下观察并比较半薄切片与石蜡切片染色结果的差异。结果石蜡切片HE和甲苯胺蓝染色均显示视神经髓鞘不着色,MBP免疫组织化学染色示MBP阳性着色较重,着色较紊乱,髓鞘着色不清晰。半薄切片HE及甲苯胺蓝染色均显示髓鞘呈环形,着色清晰,颜色对比鲜明;MBP免疫组化染色结果可见髓鞘呈环形,非特异性染色不明显,阳性对比显著,可清晰显示髓鞘结构。结论半薄切片在视神经组织学和免疫组织化学研究中优于石蜡切片,可用于视神经疾病的诊断和研究。     

两种脱钙法植被鼠尾病理切片的比较

目的探讨制作大鼠尾巴标本石蜡切片的方法。方法采用盐酸脱钙液运用两种脱钙方法制作大鼠尾巴标本石蜡切片。结果两种方法制作的石蜡切片完整、无破碎,HE染色观察组织结构细胞形态完整,核浆分明,红蓝适度。结论两种方法都能制作理想大鼠尾巴标本石蜡切片,可保证病理诊断质量。     

植物胚胎学研究中石蜡切片的几种整体染色法

石蜡切片法应用于生物学的研究历史已久,至今仍为细胞学、组织学、胚胎学及组织化学等方面广泛应用的研究方法之一。我们在观察小麦和玉米的受精及胚胎发育过程中摸索出制作石蜡切片的三种整体染色方法,使常规石蜡切片法得到了简化并且效果良好。     

大鼠泪腺睾酮受体直空负压ABC法光镜观察与免疫金探针超微结构定位

动物实验发现睾酮能改善干眼病动物模型干眼症状,促进泪腺分泌,但作用机理不明,本研究探讨泪腺细胞中是否存在睾酮受体。雌雄各8只大鼠的泪腺分别制成石蜡切片和超薄切片,睾酮分别采用ABC法及免疫金标记,通过真空负压ABC法光镜观察及免疫金探针超微结构定位进行细胞睾酮受体检查。结果：光镜下泪腺导管上皮细胞的胞浆及胞核中出现免疫染色阳性,泪腺上皮细胞则很少见到;电镜下泪腺细胞胞浆及核中可见金颗粒,对照组则染色阴性。结论 泪腺细胞存在着睾酮受体,睾酮通过受体对泪腺发生作用。     

成熟玉米秆组织结构切片方法的比较研究

于玉米成熟期选择健壮茎秆的基部第三节间为材料,采用徒手切片法、冰冻切片法、石蜡切片法、薄切片法等4种方法,比较不同方法的玉米茎秆组织结构切片质量,为研究玉米茎秆结构与其倒伏的关系奠定技术基础。结果表明:徒手切片法是获得成熟玉米秆组织结构切片较为方便、快速的方法,切片面积较大,适合大范围观察统计;冰冻切片法是获得成熟玉米秆组织结构较快的方法,切片面积较小,适合小范围观察;薄切片是获得高质量成熟玉米秆组织结构切片的最好方法,但切片面积太小,适合高倍数显微观察和小范围电镜扫描观察组织结构;石蜡切片不适合作为成熟玉米秆的组织切片方法。研究认为,徒手切片法是最适合成熟玉米秆组织结构观察研究的制片方法。     

基于改良石蜡切片技术的飞蝗胚胎浆膜表皮发育模式及形态变化观察

【目的】通过优化飞蝗Locusta migratoria胚胎石蜡切片制备技术,研究飞蝗胚胎发育时期浆膜表皮变化规律。【方法】通过优化飞蝗胚胎固定前处理、洗涤、脱水和透明等步骤,改良胚胎期石蜡切片制备技术;制备飞蝗胚胎发育第3-10天的石蜡切片,通过HE染色观察浆膜表皮发育规律;通过制备飞蝗发育第6-8天从卵孔端至卵尾端的纵切切片,观察飞蝗胚胎转旋时期的形态变化。【结果】飞蝗胚胎期石蜡切片技术优化后的操作步骤为:固定前Na Cl O预处理和打孔、洗涤30min、脱水30 min和透明30 min。通过此方法可获得表皮结构完整且清晰的胚胎期组织切片。在30℃条件下,飞蝗胚胎浆膜表皮及几丁质沉积形成于胚胎发育的第5天,在第8天时开始降解。飞蝗胚胎的转旋发生在第6-7天,伴随着浆膜和浆膜表皮的形态变化。【结论】本研究优化了飞蝗胚胎石蜡切片制备步骤,揭示了飞蝗胚胎浆膜表皮及胚胎转旋的发育模式,为昆虫胚胎发育的研究提供了基础资料。     

一种简单而快捷的半薄切片脱树脂新方法

目前,在HE染色、特殊染色或免疫组织化学染色研究方面多采用普通石蜡包埋切片,其切片厚度可薄达4μm,若更薄的切片,切割有一定的难度.对于各种染色而言,越薄的切片,细胞与组织结构越清晰,染色效果越好.环氧树脂(Epon)包埋的组织块不仅用于透射电子显微镜超薄切片的制备,也可用于光镜半薄切片的制备[1].经典的脱树脂的方法是将半薄切片置于氢氧化钠的无水乙醇饱和溶液中浸泡24h,然后再充分水洗.该法耗时长,容易脱片,本实验中摸索出一种简单而快捷的脱树脂的方法,现介绍如下.     

冰冻切片技术在植物显微结构和组织化学中的应用

介绍了冰冻切片法研究植物显微结构和组织化学的一般程序。结果表明,冰冻切片过程简单有效且图版清晰,在1d内可获得高质量图片,解决了利用普通石蜡切片观察植物样品需要进行脱水、浸透、包埋操作且耗时长的问题,在植物显微结构和组织化学研究中具有广阔的应用前景。     

声带组织切片方法的比较

目的:探讨犬声带冠状位切片与水平位切片各自的特点,为声带实验提供合适的切片方法。方法:家犬4只,2只取材后行冠状位石蜡切片,2只取材后行水平位石蜡切片。通过HE染色观察声带固有层的一般组织结构,Masson三色染色观察固有层中胶原的排列情况。结果:HE染色示冠状位、水平位切片均可见声带表面被覆复层鳞状上皮,固有层内有大量排列紧密的纤维组织,纤维组织中夹杂少量腺体,固有层下方为肌层。冠状位切片可观察声带某一点冠状面固有层的情况,若观察整个声带的情况需声带连续切片;水平位切片可在一张切片中观察到前联合、声带膜部及声带突部位的固有层情况,解剖标志明显,利于定位。Masson三色染色示冠状位、水平位切片均可见固有层浅层有较细的胶原纤维束,中层有较粗的纤维束与较细的纤维束交织排列,深层纤维束排列更紧密。结论:冠状位切片可观察声带某一点冠状面固有层的整体情况,水平位切片可在一张切片中观察到前联合、膜部及声带突部位的固有层情况。     

A Single Simple Procedure for Dewaxing,Hydration and Heat-Induced Epitope Retrieval (HIER) for Immunohistochemistry in Formalin-Fixed Paraffin-Embedded Tissue

Heat-induced epitope retrieval (HIER) is widely used for immunohistochemistry on formalin-fixed paraffin-embedded tissue and includes temperatures well above the melting point of paraffin. We therefore tested whether traditional xylene-based removal of paraffin is required on sections from paraffin-embedded tissue, when HIER is performed by vigorous boiling in 10 mM Tris/0.5 mM EGTA-buffer (pH=9). Immunohistochemical results using HIER with or without prior dewaxing in xylene were evaluated using 7 primary antibodies targeting proteins located in the cytosol, intracellular vesicles and plasma membrane. No effect of omitting prior dewaxing was observed on staining pattern. Semiquantitative analysis did not show HIER to influence the intensity of labelling consistently. Consequently, quantification of immune labelling intensity using fluorescent secondary antibodies was performed at 5 dilutions of primary antibody with and without prior dewaxing in xylene. No effect of omitting prior dewaxing on signal intensity was detectable indicating similar immunoreactivity in dewaxed and non-dewaxed sections. The intensity of staining the nucleus with the DNA-stain ToPro3 was similarly unaffected by omission of dewaxing in xylene.In conclusion, the HIER procedure described and tested can be used as a single procedure enabling dewaxing, hydration and epitope retrieval for immunohistochemistry in formalin-fixed paraffin-embedded tissue.Key words: Immunolabelling, antibodies, histology, protein localization, HIER     

Raman spectroscopic evaluation of efficacy of current paraffin wax section dewaxing agents.

During a spectroscopic study to identify biochemical changes in cervical tissue with the onset of carcinogenesis, residual paraffin wax contributions were observed on almost all dewaxed formalin-fixed paraffin-processed (FFPP) tissue sections examined. Subsequently, the present study was formulated to evaluate the efficacy of current dewaxing agents using Raman spectroscopy. Three cervical FFPP sections were subjected to each of the protocols. Sections were dewaxed using four common dewaxing protocols, namely, xylene, Histoclear, heat-mediated antigen retrieval (HMAR) using xylene and citrate buffer, and Trilogy (combined deparaffinization and unmasking of antigens). The potential for hexane as a dewaxing agent was also evaluated. Sections were dewaxed in multiple dewaxing cycles using xylene, Histoclear, and hexane. Residual paraffin wax contributions remained at 1062 cm(-1), 1296 cm(-1), and 1441 cm(-1). HMAR using xylene and citrate buffer, and HMAR using Trilogy, showed a similar efficacy, resulting in incomplete removal of wax. Hexane was shown to be the most effective dewaxing agent, resulting in almost complete removal of wax. Immunohistochemistry was carried out on dewaxed slides, and those dewaxed with hexane displayed a stronger positivity (approximately 28%). Implications for histopathology and immunohistochemistry are considered, as well as problems that residual wax poses for spectroscopic evaluation of dewaxed FFPP sections with a view to disease diagnosis.     

Letters to the Editor

Abstract

Hot commercial dishwashing detergent has been used to deparaffinize and hydrate formalin fixed, paraffin embedded sections for immunohistochemistry. Fifty-five antibodies, used routinely for diagnosis, were used to compare hot detergent dewaxing with the proprietary hydrocarbon-based dewaxing reagent supplied with the Bond Max immunohistochemistry system^®. A 2% concentration of commercial dishwashing detergent in distilled water was heated to 90° C and paraffin sections were treated twice for 1 min each. Nearly all antibodies gave equivalent results except CD10 and CD57 (hydrocarbon-based dewaxing better) and CD45 and alpha fetoprotein (detergent dewaxing better); the differences, however, were minimal. There also was a significant cost saving using detergent dewaxing.     

Deparaffination time: a crucial point in histochemical detection of tissue copper

The search for a sensitive histochemical method for revealing tissue copper has been the object of many workers in the past. In spite of multiple methods available, the occurrence in clinical practice of negative histochemical stains, even in cases with high copper levels demonstrated by quantitative methods is very high.This study was aimed at verifying the role of technical variations in the sensitivity of the Timm method and, in particular, the role of the dewaxing time of paraffin sections. To this end, 15 liver specimens, 10 from patients affected by Wilson's disease and 5 newborn livers were fixed in 10% formalin, paraffin embedded and routinaly processed. Four 4-micron sections from each case were rinsed in xylene for 10, 20, 60 min, and for 24 hrs. All sections were stained with Timm's method. In 13 out of the 15 liver biopsies utilized in this study, the sensitivity of Timm's method in revealing copper deposits in liver cells appeared to be dependent on the dewaxing time. In two other cases, reactivity of copper granules to Timm solution did not change significantly with the different deparaffination times. The best results were obtained by rinsing sections in xylene for 24 hrs, the worst in sections treated with xylen for 10 minutes. In particular, in five cases of Wilson's disease, Timm stain applied to sections following ten minutes of xylene were completely negative, while copper granules were clearly evidenced in the same section following an overnight bath in xylene. Our data show that an overnight bath of paraffin sections in xylene may completely change the sensitivity of Timm stain in revealing copper deposits in the liver, relaunching copper histochemistry in the diagnosis of copper-related liver diseases.     

A simple method for studying whole sections of rice grain

We developed a new and simple method to collect sections of a whole brown rice kernel for investigation of histological properties. A single kernel of rice was dehydrated through a graded ethanol series, transferred to xylene, and embedded in paraffin. During sectioning of the blocks using a rotary microtome, we used a special adhesive tape to collect and place the sections on slides so they remained flat. The use of the adhesive tape technique combined with autofluorescence characteristics allowed us to visualize cell walls throughout an entire longitudinal or transverse section of a whole rice kernel. We obtained scanning electron microscopy images of the sections to determine section quality.     

A simple method for studying whole sections of rice grain

We developed a new and simple method to collect sections of a whole brown rice kernel for investigation of histological properties. A single kernel of rice was dehydrated through a graded ethanol series, transferred to xylene, and embedded in paraffin. During sectioning of the blocks using a rotary microtome, we used a special adhesive tape to collect and place the sections on slides so they remained flat. The use of the adhesive tape technique combined with autofluorescence characteristics allowed us to visualize cell walls throughout an entire longitudinal or transverse section of a whole rice kernel. We obtained scanning electron microscopy images of the sections to determine section quality.     

A simple and rapid microwave-assisted hematoxylin and eosin staining method using 1,1,1 trichloroethane as a dewaxing and a clearing agent

The use and practicability of microwave-assisted staining procedures in routine histopathology has been well established for more than 17 years. In the study reported here, we aimed to examine an alternative approach that would shorten the duration of dewaxing and clearing steps of hematoxylin and eosin (H & E) staining of paraffin sections by using a microwave oven. Although xylene is one of the most popular dewaxing and clearing agents, its flammability restricts its use in a microwave oven; thus we preferred 1,1,1 trichloroethane, which is not flammable, as the dewaxing and clearing agent in the present study. In Group I and Group II (control groups), intestine was processed with xylene and 1,1,1 trichloroethane, respectively. The sections were then stained with H & E according to the conventional staining protocol at room temperature and subdivided into two groups according to the duration of dewaxing and clearing in xylene. In Groups III and IV (experimental groups) similar tissues were processed with xylene and 1,1,1 trichloroethane, respectively; however, sections from these groups were divided into four subgroups to study the period required for dewaxing and clearing in 1,1,1 trichloroethane, then stained with H & E in the microwave oven at 360 W for 30 sec. Our conventional H & E staining procedure, which includes dewaxing, staining and clearing of sections, requires approximately 90 min, while our method using 1,1,1 trichloroethane and microwave heating required only 2 min. Our alternative method for H & E staining not only reduced the procedure time significantly, but also yielded staining quality equal or superior to those stained the conventional way. Our results suggest that 1,1,1 trichloroethane can be used effectively and safely as a dewaxing and clearing agent for H & E staining in a microwave oven.     

A simple and rapid microwave-assisted hematoxylin and eosin staining method using 1,1,1 trichloroethane as a dewaxing and a clearing agent.

The use and practicability of microwave-assisted staining procedures in routine histopathology has been well established for more than 17 years. In the study reported here, we aimed to examine an alternative approach that would shorten the duration of dewaxing and clearing steps of hematoxylin and eosin (H & E) staining of paraffin sections by using a microwave oven. Although xylene is one of the most popular dewaxing and clearing agents, its flammability restricts its use in a microwave oven; thus we preferred 1,1,1 trichloroethane, which is not flammable, as the dewaxing and clearing agent in the present study. In Group I and Group II (control groups), intestine was processed with xylene and 1,1,1 trichloroethane, respectively. The sections were then stained with H & E according to the conventional staining protocol at room temperature and subdivided into two groups according to the duration of dewaxing and clearing in xylene. In Groups III and IV (experimental groups) similar tissues were processed with xylene and 1,1,1 trichloroethane, respectively; however, sections from these groups were divided into four subgroups to study the period required for dewaxing and clearing in 1,1,1 trichloroethane, then stained with H & E in the microwave oven at 360 W for 30 sec. Our conventional H & E staining procedure, which includes dewaxing, staining and clearing of sections, requires approximately 90 min, while our method using 1,1,1 trichloroethane and microwave heating required only 2 min. Our alternative method for H & E staining not only reduced the procedure time significantly, but also yielded staining quality equal or superior to those stained the conventional way. Our results suggest that 1,1,1 trichloroethane can be used effectively and safely as a dewaxing and clearing agent for H & E staining in a microwave oven.     

A simple and rapid microwave-assisted hematoxylin and eosin staining method using 1,1,1 trichloroethane as a dewaxing and a clearing agent

The use and practicability of microwave-assisted staining procedures in routine histopathology has been well established for more than 17 years. In the study reported here, we aimed to examine an alternative approach that would shorten the duration of dewaxing and clearing steps of hematoxylin and eosin (H & E) staining of paraffin sections by using a microwave oven. Although xylene is one of the most popular dewaxing and clearing agents, its flammability restricts its use in a microwave oven; thus we preferred 1,1,1 trichloroethane, which is not flammable, as the dewaxing and clearing agent in the present study. In Group I and Group II (control groups), intestine was processed with xylene and 1,1,1 trichloroethane, respectively. The sections were then stained with H & E according to the conventional staining protocol at room temperature and subdivided into two groups according to the duration of dewaxing and clearing in xylene. In Groups III and IV (experimental groups) similar tissues were processed with xylene and 1,1,1 trichloroethane, respectively; however, sections from these groups were divided into four subgroups to study the period required for dewaxing and clearing in 1,1,1 trichloroethane, then stained with H & E in the microwave oven at 360 W for 30 sec. Our conventional H & E staining procedure, which includes dewaxing, staining and clearing of sections, requires approximately 90 min, while our method using 1,1,1 trichloroethane and microwave heating required only 2 min. Our alternative method for H & E staining not only reduced the procedure time significantly, but also yielded staining quality equal or superior to those stained the conventional way. Our results suggest that 1,1,1 trichloroethane can be used effectively and safely as a dewaxing and clearing agent for H & E staining in a microwave oven.     

Immunohistochemistry: paraffin sections using the Vectastain ABC kit from vector labs

Immunohistochemistry (IHC) is a valuable technique utilized to localize/visualize protein expression in a mounted tissue section using specific antibodies. There are two methods: the direct and indirect method. In this experiment, we will only describe the use of indirect IHC staining. Indirect IHC staining utilizes highly specific primary and biotin-conjugated secondary antibodies. Primary antibodies are utilized to discretely identify proteins of interest by binding to a specific epitope, while secondary antibodies subtract for non-specific background staining and amplify signal by forming complexes to the primary antibody. Slides can either be generated from frozen sections, or paraffin embedded sections mounted on glass slides. In this protocol, we discuss the preparation of paraffin-embedded sections by dewaxing, hydration using an alcohol gradient, heat induced antigen retrieval, and blocking of endogenous peroxidase activity and non-specific binding sites. Some sections are then stained with antibodies specific for T cell marker CD8 and while others are stained for tyrosine hydroxylase. The slides are subsequently treated with appropriate secondary antibodies conjugated to biotin, then developed utilizing avidin-conjugated horseradish peroxidase (HRP) with Diaminiobenzidine (DAB) as substrate. Following development, the slides are counterstained for contrast, and mounted under coverslips with permount. After adequate drying, these slides are then ready for imaging.