Colorimetry for the stain technologist. IV. Analysis of the components of color difference

Total color differences have been calculated for various pairs of stained microscopic substrates. The latter include azure B/eosin stained blood cells and Papanicolaou stained cells from the uterine cervix. Both the CIE L*u*v* and L*a*b* color spaces have been used. Total color differences have been analyzed in terms of lightness, hue and chroma components. Various discrepancies have been noted among these components, especially the chroma difference, for the two spaces. It is concluded that current color-difference formulae are less than perfect, although they can provide much useful information.     

The influence of Romanowsky-Giemsa type stains on nuclear and cytoplasmic features of cytological specimens

The aim of the present study was to compare the staining pattern of the standard azure B-eosin Y stain with commercial May-Grünwald-Giemsa (MGG) stains on cytological specimens by means of high resolution image analysis. Several cytological specimens (blood smears, abdominal serous effusions, bronchial scrape material) were air dried, methanol fixed and stained with the standard azure B-eosin Y stain and with commercial May-Grünwald-Giemsa stains. Integrated optical density (IOD) and colour intensities of cell nuclei and cytoplasm were measured with the IBAS 2000 image analyser. Commercial MGG stains gave much higher coefficients of variation for all parameters than the standard stain. Reproducibility of cell nuclei segmentation versus cytoplasm was significantly better for the standard stain. Contamination of the standard stain with methylene blue partly copied the staining pattern of commercial stains. The standard azure B-eosin Y stain is recommended for high resolution image analysis (HRIA) of cytological samples.     

Romanowsky dyes and the Romanowsky-Giemsa effect. 3. Microspectrophotometric studies of Romanowsky-Giemsa staining. Spectroscopic evidence of a DNA-azure B-eosin Y complex producing the Romanowsky-Giemsa effect

The Romanowsky-Giemsa staining (RG staining) has been studied by means of microspectrophotometry using various staining conditions. As cell material we employed in our model experiments mouse fibroblasts, LM cells. They show a distinct Romanowsky-Giemsa staining pattern. The RG staining was performed with the chemical pure dye stuffs azure B and eosin Y. In addition we stained the cells separately with azure B or eosin Y. Staining parameters were pH value, dye concentration, staining time etc. Besides normal LM cells we also studied cells after RNA or DNA digestion. The spectra of the various cell species were measured with a self constructed microspectrophotometer by photon counting technique. The optical ray pass and the diagramm of electronics are briefly discussed. The nucleus of RG stained LM cells, pH congruent to 7, is purple, the cytoplasm blue. After DNA or RNA digestion the purple respectively blue coloration in the nucleus or the cytoplasm completely disappeares. Therefore DNA and RNA are the preferentially stained biological substrates. In the spectrum of RG stained nuclei, pH congruent to 7, three absorption bands are distinguishable: They are A1 (15400 cm-1, 649 nm), A2 (16800 cm-1, 595 nm) the absorption bands of DNA-bound monomers and dimers of azure B and RB (18100 cm-1, 552 nm) the distinct intense Romanowsky band. Our extensive experimental material shows clearly that RB is produced by a complex of DNA, higher polymers of azure B (degree of association p greater than 2) and eosin Y. The complex is primarily held together by electrostatic interaction: inding of polymer azure B cations to the polyanion DNA generates positively charged binding sites in the DNA-azure B complex which are subsequently occupied by eosin Y anions. It can be spectroscopically shown that the electronic states of the azure B polymers and the attached eosin Y interact. By this interaction the absorption of eosin Y is red shifted and of the azure B polymers blue shifted. The absorption bands of both molecular species overlap and generate the Romanowsky band. Its strong maximum at 18100 cm-1 is due to the eosin Y part of the DNA-azure B-eosin Y complex. The discussed red shift of the eosin Y absorption is the main reason for the purple coloration of RG stained nuclei. Using a special technique it was possible to prepare an artificial DNA-azure B-eosin Y complex with calf thymus DNA as a model nucleic acid and the two dye stuffs azure B and eosin Y.(ABSTRACT TRUNCATED AT 400 WORDS)     

Colorimetry for the Stain Technologist. IV. Analysis of the Components of Color Difference

Total color differences have been calculated for various pairs of stained microscopic substrates. The latter include azure B/eosin stained blood cells and Papanicolsou stained cells from the uterine cervix. Both the CIE Luv and Lab color spaces have been used. Total color differences have been analyzed in terms of lightness, hue and chroma components. Various discrepancies have been noted among these components, especially the chroma difference, for the two spaces. It is concluded that current color-difference formulae are less than perfect, although they can provide much useful information.     

Comparative colorimetry in cytophotometric measurements of azure B-eosin Y-stained and Giemsa-stained blood cell smears

The advantages of the Commission Internationale de l'Eclairage (CIE) color measurements and the use of the standardizable purified azure B-eosin Y stain, as compared to the commonly used commercial Giemsa stain, were studied. Color measurement and analysis according to the CIE standards allows the comparison of color measurements from different slides stained by either the same or different procedures. Moreover, measurements from different cytophotometric systems can be compared. The results can also be directly correlated with human visual subjective color estimates and thus used to quantify the human observations. The color information in the air-dried cell specimens, which differs from the color characteristics of the components of the staining solution, was measured and analyzed.     

Understanding Romanowsky staining. I: The Romanowsky-Giemsa effect in blood smears

Normal blood smears were stained by the standardised azure B-eosin Y Romanowsky procedure recently introduced by the ICSH, and the classical picture resulted. The effects of varying the times and temperature of staining, the composition of the solvent (buffer concentration, methanol content, & pH), the concentration of the dyes, and the mode of fixation were studied. The results are best understood in terms of the following staining mechanism. Initial colouration involves simple acid and basic dyeing. Eosin yields red erythrocytes and eosinophil granules. Azure B very rapidly gives rise to blue stained chromatin, neutrophil specific granules, platelets and ribosome-rich cytoplasms; also to violet basophil granules. Subsequently the azure B in certain structures combines with eosin to give purple azure B-eosin complexes, leaving other structures with their initial colours. The selectivity of complex formation is controlled by rate of entry of eosin into azure B stained structures. Only faster staining structures (i.e. chromatin, neutrophil specific granules, and platelets) permit formation of the purple complex in the standard method. This staining mechanism illuminates scientific problems (e.g. the nature of 'toxic' granules) and assists technical trouble-shooting (e.g. why nuclei sometimes stain blue, not purple).     

Understanding Romanowsky staining

Summary Normal blood smears were stained by the standardised azure B-eosin Y Romanowsky procedure recently introduced by the ICSH, and the classical picture resulted. The effects of varying the times and temperature of staining, the composition of the solvent (buffer concentration, methanol content, & pH), the concentration of the dyes, and the mode of fixation were studied. The results are best understood in terms of the following staining mechanism. Initial colouration involves simple acid and basic dyeing. Eosin yields red erythrocytes and eosinophil granules. Azure B very rapidly gives rise to blue stained chromatin, neutrophil specific granules, platelets and ribosome-rich cytoplasms; also to violet basophil granules. Subsequently the azure B in certain structures combines with eosin to give purple azure B-eosin complexes, leaving other structures with their initial colours. The selectivity of complex formation is controlled by rate of entry of eosin into azure B stained structures. Only faster staining structures (i.e. chromatin, neutrophil specific granules, and platelets) permit formation of the purple complex in the standard method. This staining mechanism illuminates scientific problems (e.g. the nature of toxic granules) and assists technical trouble-shooting (e.g. why nuclei sometimes stain blue, not purple).To whom offprint should be sent     

Microspectrophotometric studies of Romanowsky stained blood cells. III. The action of methylene blue and azure B

The performances of two standardized Romanowsky stains (azure B/eosin and azure B/methylene blue/eosin) have been compared with each other and with a methylene blue/eosin stain. Visible-light absorbance spectra of various hematological substrates have been measured. These have been analyzed in terms of the quantities of bound azure B, methylene blue and eosin dimers and monomers, and in terms of the CIE color coordinates. It has been found that the addition of methylene blue to azure B/eosin produces little change in performance, at least using these two analytical methods. Methylene blue/eosin does not produce the purplish colorations typical of the Romanowsky effect. This is due not to differences between the spectra of methylene blue and azure B, but to the fact that methylene blue does not facilitate the binding of eosin to cellular substrates to the same extent as azure B.     

Microspectrophotometric Studies of Romanowsky Stained Blood Cells. III. The Action of Methylene Blue and Azure B

The performances of two standardized Romanowsky stains (azure B/eosin and azure B/methylene blue/eosin) have been compared with each other and with a methylene blue/eosin stain. Visible-light absorbance spectra of various hematological substrates have been measured. These have been analyzed in terms of the quantities of bound azure B, methylene blue and eosin dimers and monomers, and in terms of the CIE color coordinates. It has been found that the addition of methylene blue to azure B/eosin produces little change in performance, at least using these two analytical methods. Methylene blue/eosin does not produce the purplish colorations typical of the Romanowsky effect. This is due not to differences between the spectra of methylene blue and azure B, but to the fact that methylene blue does not facilitate the binding of eosin to cellular substrates to the same extent as azure B.     

Zinc Chloride Methylene Blue, Ii. Preparation of Giesma and Wright Type Low Azure B Blood Stains from Dichromate Oxidized Commercial Dye

TO determine the amount of K₂Cr₂O₇ required to produce optimal Giemsa type staining, six 1 g amounts (corrected for dye content) of zinc methylene blue were oxidized with graded quantities of K₂Cr₂O₇ to produce 4, 8, 12, 16, 20 and 24% conversion of methylene blue to azure B. These were heated with a blank control 15 minutes at 100 C in 60-65 ml 0.4 N HCI. cooled, and adjusted to 50 ml to give 20 mg original dye/ml. Aliquots were then diluted to 1% and stains were made by the “Wet Giemsa” technic (Lillie and Donaldson 1979) using 6 ml 1% polychrome methylene blue, 4 ml 1% cosin (corrected for dye content), 2 ml 0.1 M pH 6.3 phosphate buffer, 5 ml acetone, and 23 ml distilled water. The main is added last and methanol fixed blood films are stained immediately for 20-40 min.

For methylene blue supplied by MCB 12-H-29, optimal stains were obtained with preparations containing 20 and 24% conversion of methylene blue to azure B. With methylene blue supplied by Aldrich (080787), 16% conversion of methylene blue to azure B was optimal. Eosinates prepared from a low azure B/methylene blue preparation selected in this way give good stains when used as a Wright stain in 0.3% methanol solution. However, when the 600 mg eosinate solution in glycerol methanol is supplemented with 160 mg of the same azure B/methylene blue chloride the mixture fails to perform well. The HCI precipitation of the chloride apparently produces the zinc methylene blue chloride salt which is poorly soluble in alcohol. It appears necessary to have a zinc-free azure B/methylene blue chloride to supplement the probably zinc-free eosinate used in the Giemsa mixture.     

Azure B-Eosin APAAP Staining: a Method for Simultaneous Hematological and Immunological Cell Analysis

Azure B-eosin APAAP staining allows simultaneous analysis of peripheral blood and bone marrow cells for hematological characteristics and immunological cell marker profiles. A defined sequence of staining procedures maintains characteristic components of the Romanowsky-Giemsa stain whereas cell antigens can be detected immunologically using the alkaline phosphatase-anti-alkaline phosphatase (APAAP) detection system. Antigens are visualized by the staining product of the substrate-naphthol AS GR phosphate and variamine blue salt. The usefulness of the azure B-eosin APAAP method was demonstrated on blood and bone marrow smears of patients with various hematological disorders.     

A Spectrophotometry Analysis of Tissue Staining

By comparing spectral absorption curves of representative staining solutions and of substances stained with these solutions it is shown that information may be obtained regarding chemical changes associated with the staining process. The stains used in these determinations were acid fuchsin, anilin blue, azo-carmine G, basic fuchsin, eosin Y, orange G, picric acid and Sudan IV. The substrates stained were gelatin, tendon, blood plasma, thymus gland and fat.

Aqueous basic fuchsin and fuchsin-sulfurous reagent to which formalin was added (Setoff reaction) are different stains. The spectral absorption curves for staining solutions and substances stained with the solutions were comparable. Within the limitations of the spectrophotometry methods and stains employed, there was no evidence of significant chemical alteration in the chromophore radicals of the stains associated with the process of tissue staining.     

Giemsa Stain for the Diagnosis of Bovine Babesiosis. II. Changes in Erythrocytes Infected with Babesia bigemina and B. argentina

SYNOPSIS. Cytoplasmic stippling, intensification of the cell margin, and alterations in color, which have been reported in erythrocytes parasitized by Plasmodium falciparum in man, have been seen also in bovine erythrocytes parasitized by either Babesia bigemina or B. argentina. These changes appear to be identical in the human and bovine infections.
Tests with each component of Giemsa stain in simple aqueous solutions alone and in various combinations with eosin, together with tests with Giemsa stains containing one azure component, showed that demonstration of the changes depends on the presence of azure A and eosin and on prolonged staining times at pH 7.2 to 7.4. Specific tests suggested that the changes represent catabolic by-products of the parasites.     

Zinc Chloride Methylene Blue. I. Biological Stain History, Physical Characteristics and Approximation of Azure B Content of Commercial Samples

Zinc chloride methylene blue appeared on the market almost contemporaneously with the zinc-free medicinal form. The former has rarely been reported as being used in blood stains. Recent suspension of manufacture of medicinal methylene blue by it. principal American producer has excited interest in the use of the zinc chloride form for the preparation of blood stains. According to Lillie (1944a,b) the azure B content of zinc chloride methylene blue may have varied from 5 to 30% in the samples studied. Taking the Merck Index (1968, 1976) figures for the spectroscopic absorption maximum (λmax) of 667.8 and 668 nm as standard, recent samples of zinc chloride methylene blue are calculated to contain 6-8% azure B. These figures are baaed on 1) the shift of λmax after exhaustive pH 9.5 chloroform extraction, 2) evaluation of the actual ratio of the observed TiCl₂ dye content to the theoretical for pure zinc chloride methylene blue, 3) comparison of spectroscopic and staining effects of graded hot dichromate oxidation products with those of highly purified azure B-methylene blue mixtures of known proportions.

As far as can be found, medicinal methylene blue is almost the exclusive source of cosin polychrome methylene blue blood stains. Lillie (1944c) included a short series comparing 5 zinc chloride methylene blues with a dozen medicinal methylene blue samples; all were oxidized with hot dichromate to produce successful Wright stains. No effort was made to remove the zinc Exhaustive pH 9.5 chloroform extraction of zinc chloride methylene blue (lot MCB 12-H-29) yielded a small amount of red dye which when extracted into 0.1 N HCI gave λmax = 650. The extraction moved the absorption peak of the zinc chloride methylene blue from 667 to 668 nm and the midpoint of the 90% maximum absorption band, 18 nm wide, from 666.5 to 667.5 nm.     

Lower Azure B Methylene Blue Ratios in Giemsa Type Blood and Malaria Stains

Starting from ancient reports that rare samples of methylene blue were apparently sufficiently contaminated with azures to give red plasmodial and red purple nuclear chromatin in Chenzinsky type methylene blue eosin stains, it was decided to determine how little azure B would suffice for such staining in methylene blue eosin stains. The traditional 1902 Giemsa had an azure:methylene blue: eosin ratio of about 6:3:6.3:10; Lillie's 1943 formula had a 5:7:10 ratio. In the current series of tests 5:7:10 (I), 4:8:10 (II), 3:9:10 (III), 2:10:10 (IV), 1:11:10 (V), and 0:12:10 (VI) were used. Malaria and blood stains were better than the standard 5:7:10 (I) in III, IV and II in that order. Normal and leukemic human blood, mouse blood with Plasmodium berghei, and monkey blood with the CDC strain of Pl. falciparum were used as test materials. The staining mixtures were made from highly purified samples of azure B and methylene blue. Staining mixtures contained 12 ml 0.1% thiazin dye, 10 ml 0.1% eosin, 2 ml each of glycerol, methanol and 0.1 M phosphate buffer pH 6.5, 3 ml acetone as accelerator, and distilled water to make 40 ml; staining times of 10-30 min were used.     

冬虫夏草、蛹虫草菌丝隔膜和细胞核荧光染色

冬虫夏草和蛹虫草作为重要的药用真菌,得到广泛的重视,迄今已有大量的研究报道。然而,作为细胞学研究的基础处理方法,其菌丝隔膜和细胞核染色却缺乏必要的研究。荧光染色是一种程序简便、快速灵敏的染色方法。本研究选用DAPI、PI、Calcoflour White和刚果红等4种染料,对冬虫夏草、蛹虫草菌丝的隔膜和细胞核进行单独与组合染色实验,通过显微观察比较得出较好的染色方法。结果表明DAPI对冬虫夏草和蛹虫草菌丝的细胞核染色效果都较好,而Calcoflour White对两者的细胞壁染色效果较好且隔膜清晰。DAPI与Calcoflour White两者进行冬虫夏草菌丝组合染色的效果为最佳,但在蛹虫草菌丝染色中效果不太稳定。对蛹虫草菌丝较好的组合染色是DAPI与刚果红的组合,但其染色结果需要在激光共聚焦显微镜下观察。     

Can azur-B eosin replace the May-Grünwald-Giemsa stain?]

A new method is described for staining blood and bone marrow smears. It is characterized by the presence of only two dyes, purified azure B and eosin in methanol, as stock solutions. Staining results are equivalent to those obtained by using the traditional dye mixtures according to May and Grunwald, Giemsa, Leishman or Wright. Different from these azure B-eosin staining can be standardized and is easier to be handled. Correlations between the azure-B-eosin and May-Grunwald-Giemsa (MGG) staining methods are briefly discussed.     

Objective evaluation of treatment effects on port-wine stains using L*a*b* color coordinates

Wide variations in port-wine stains and their responses to various therapies pose a need for the development of an objective method to evaluate the effects of treatment. Several techniques such as laser Doppler, reflectance spectrometry, and tristimulus colorimetry have been used to evaluate the color of port-wine stains, but these techniques are limited by cost, small test size area, and other factors. Therefore, we developed a simple and cost-effective method of evaluating treatment results on port-wine stains using the L*a*b* color coordinate system in combination with a personal computer. For 22 patients with port-wine stains, the slide photographs were digitized using a slide scanner. L*a*b* color differences of the normal control and port-wine stain sites were obtained before and after treatment, and treatment effect (percent) was calculated. By calculating each color difference between the lesion and normal skin both before and after treatment, problems arising from different illuminating conditions during photography were minimized. The results were compared with the visual evaluation conducted by three experienced plastic surgeons. The treatment effects analyzed by L*a*b* color coordinate ranged from 4 to 95 percent, with a mean of 48.1 percent, whereas treatment effects evaluated by the plastic surgeons ranged from 15 to 92 percent, with a mean of 51.1 percent. The subjective clinical grades correlated well with the treatment effects obtained by the proposed color analysis system (correlation coefficient, 0.89). The maximum difference in the effect of treatment for a patient evaluated by the three clinicians was up to 60 percent, which means that visual judgment is very subjective and variable. The color analysis system proposed as a result of this study is very easy, objective, quantitative, cost-effective, and can be useful for the evaluation of treatment effects on colored skin lesions such as port-wine stains.     

紫茉莉开花过程中花色和花色素的变化规律

紫茉莉是我国广泛分布的庭院花卉之一,具有丰富的花色。但不同花色紫茉莉在开花过程中的花色变化规律及其呈色机制还不清楚。以紫红色、黄色和白色紫茉莉为研究对象,分别通过色差仪测定法和紫外-可见分光光度法测定了不同开花时期不同花色紫茉莉花色表型及各类色素含量,探讨了其花色和色素变化规律,揭示其呈色机制。结果表明,从花蕾期到盛开期,紫红色紫茉莉花冠由淡绿色转变为紫红色,明度L^*值和色相b^*值减小,而色相a^*值、色度C^*值和色度角h值增大,叶绿素含量逐渐下降,类胡萝卜素、花色素苷和总黄酮含量逐渐升高;黄色紫茉莉花冠由淡绿色转变为黄色,盛开期具有最高的色度C^*值、色相a^*值和b^*值,整个开花过程具有较稳定的叶绿素和总黄酮含量,同时具有较高的类胡萝卜素含量;白色紫茉莉花冠由淡绿色转变为白色,过渡期具有最高的明度L^*值、色度C^*值、色相a^*值和b^*值,整个开花过程花色素苷和总黄酮含量较低,但随着开花进程逐渐升高,而类胡萝卜素含量稳定,过渡期总叶绿素含量显著低于其他2个时期。可见,不同花色紫茉莉开花过程中花色变化规律存在差异,而其差异性与其相应的色素成分变化密切相关。     

楸树不同单株花性状变异分析

楸树是我国中部地区重要的珍贵阔叶用材和著名的园林观赏树种,已有2 600多年的栽培历史。研究其花性状多样性与变异性旨在揭示花表型性状在楸树种内存在的巨大变异,为新花色育种和优良观花新品种的选育及新品种的鉴定和保护提供理论依据。以1985~1990年收集的优良单株和杂种F1共27株为材料,测定了花性状中的2个质量性状和7个数量性状,并采用方差分析、聚类分析等方法进行统计分析。①27株的开花物候期差异可达5 d,花大小、花序长短和单株花量均有较大差异,并且由于叶柄长度和花枝长度的差异导致不同单株表现出显花和隐花特征。②楸树为二强雄蕊,分为雄性可育和败育,调查的27株中有12株为雄性可育,且花粉量差异较大。③花冠檐部5裂,上唇3瓣,下唇2瓣,上唇瓣长度大于下唇瓣。27株的花枝长度、花序长度、单花枝花数、花上唇瓣长度、花下唇瓣长度和花冠直径均存在极显著差异,单株间的变幅分别为10.7~16.4 cm、5.6~9.6cm、2~13朵、3.8~5.2 cm、3.0~4.3 cm、3.9~5.4 cm,表型变异系数分别为12.8%、12.5%、36.7%、7.5%、9.1%和9.2%。④16株间花色L^*值(亮度值)、a^*值(红绿值)、b^*值(黄蓝值)、C^*值(彩度)和h值(色相)均存在极显著差异,a^*值、b^*值以及彩度C^*值的表型变异系数分别为35.1%、52.5%和29.8%;以L^*、a^*和b^*值度量花色,通过聚类分析将16株聚为3类,红色系、粉红色系和白色系。楸树27株的花枝长度、花序长度、花大小差异极显著,16株的花色也具有明显的差别,依据L^*、a^*和b^*值进行聚类分析,当欧氏距离为15时可将16株聚为3类:红色系、粉红色系和白色系。