Staining Sulfated Mucopolysaccharides in Sections by Means of Acriflavine

Acriflavine gave insoluble salts with sulfated esters. Frozen or paraffin sections (fixed in 10% formol or Carnoy's solution) were stained in M/20 acriflavine solution and excess dye was rinsed in 95% alcohol. Then nuclei were stained with Meyer's haemalum. Thereafter the sections were washed in water, dehydrated in alcohol, cleared in xylene and mounted in balsam. Sulfated esters in the tissue sections were colored yellow or orange-yellow, generally more densely in frozen than in paraffin sections.     

Fink-Heimer Silver Impregnation of Degenerating Axons and Terminals in Mounted Cryostat Sections of Fresh and Fixed Brains

The silver impregnation method of Fink and Heimer (Brain Res., 4: 369-74, 1967) has been used on cryostat sections of both fresh frozen and formalin-fixed brain tissue mounted on slide. The fixed brains were soaked in 25% sucrose for 2-3 days before freezing. The slides used for mounting were dipped in a 0.5% aqueous gelatin solution containing 50 mg of chrome-alum per 100 ml, drained and allowed to dry in a vertical position. Sections of fresh tissue were fixed for 16 hr in a 10% formalin solution buffered with phosphates to pH 7.0. Staining was carried out according to the Fink-Heimer procedure II and gave results comparable to those obtained on unmounted frozen sections of formalin-fixed material     

Fink-Heimer Silver Impregnation of Degenerating Axons and Terminals in Mounted Cryostat Sections of Fresh and Fixed Brains

The silver impregnation method of Fink and Heimer (Brain Res., 4: 369-74, 1967) has been used on cryostat sections of both fresh frozen and formalin-fixed brain tissue mounted on slide. The fixed brains were soaked in 25% sucrose for 2-3 days before freezing. The slides used for mounting were dipped in a 0.5% aqueous gelatin solution containing 50 mg of chrome-alum per 100 ml, drained and allowed to dry in a vertical position. Sections of fresh tissue were fixed for 16 hr in a 10% formalin solution buffered with phosphates to pH 7.0. Staining was carried out according to the Fink-Heimer procedure II and gave results comparable to those obtained on unmounted frozen sections of formalin-fixed material     

Immunocytochemical localization of nerve growth factor: effects of fixation

The fixation dependence of immunocytochemically demonstrable nerve growth factor (NGF) was investigated. Several commonly used fixation methods have been employed, including buffered formaldehyde, Bouin's fluid, and chloroform-methanol, as well as freezing and cryostat sectioning. The immunostaining technique was an immunoenzyme bridge procedure on either paraffin sections or frozen sections. Of those methods tested, fixation for 1 hr in a buffered formaldehyde appeared to provide optimal preservation and localization of immunoreactive material. Using this method, reaction product was localized in granules of the granular tubule cells of the male mouse submandibular gland. Prolonged fixation in buffered formaldehyde resulted in a diffuse background staining and loss of granule immunoreactivity. In frozen sections and in tissues fixed with either Bouin's solution, chloroform-methanol, or buffered paraformaldehyde-glutaraldehyde increased cytoplasmic background staining and loss of granule immunoreactivity were observed. It was concluded that, for the localization of NGF at the light microscopic level, a brief (1 hr) buffered formaldehyde fixation is optimal.     

A modified semipermeable membrane technique for carbonic anhydrase histochemistry of the nervous system

We present a modification of Hansson's method for the demonstration of carbonic anhydrase activity. Using a semipermeable membrane together with a fluid incubation medium, frozen sections of aldehyde-fixed tissue were incubated without floating or dipping. Thin sections (thickness, 20-40 microns) were mounted on the outer surface of a tubular-shaped, semipermeable cellophane dialysis membrane containing the incubation fluid. After incubation for 25-30 min at room temperature, the sections were rinsed in buffer and treated with 0.5% (NH4)2S solution. The histochemical reaction was fully inhibited by 10(-4) M acetazolamide.     

Histochemical localization of glutathione in tissues.

A histochemical method has been developed for the localization of glutathione (GSH) in frozen sections from various tissues including liver, lung, kidney, testis and eye. The reliability and specificity of the method has been investigated by comparing the rates of reaction in tissue and gelatin sections and after depletion of GSH in liver by diethyl maleate. In principle, the method is based on the formation of an irreversible complex of mercury orange with the --SH group of GSH. A 5-min staining period was found to be optimal for staining the --SH group of GSH. In brief, frozen sections 8 mu thick are stained with a 50 muM solution of mercury orange dissolved in toluene, counterstained in 0.05 per cent methylene blue and mounted in Histoclad. Pretreatment of the sections with fixatives or drying them in air completely prevented the staining. In hepatic lobules the brick red granules of the GSH mercury orange complex were distributed uniformly, whereas in other tissues they were not uniform. The GSH staining was localized in the proximal convoluted tubules in the cortex of the kidney, the interalveolar epithelial cells of lungs, the epididymis and the capsule of testis, epithelial cells of vas deferens and the periphery of the lens.     

适合于植物花器官的冰冻切片技术

通过对4种植物主要花器官冰冻切片技术的各个环节及参数的研究,建立了一种适合于植物花器官的冰冻切片技术,即蔗糖保护-液氮速冻-冰冻切片法。其具体程序是：材料经固定和冷冻保护(蔗糖为冷冻保护剂)后进行速冻包埋(液氮为包埋剂);尔后进行冰冻切片;切片经干燥和染色(或者不染色)后,在显微镜下观察并摄影。此法为植物花器官的细胞生物学和分子生物学研究提供了简便、快速和高效的切片技术。     

Application of microwave technology to the processing and immunolabeling of plastic-embedded and cryosections.

We have adapted existing microwave irradiation (MWI) protocols and applied them to the processing and immunoelectron microscopy of both plastic-embedded and frozen sections. Rat livers were fixed by rapid MW irradiation in a mild fixation solution. Fixed liver tissue was either cryosectioned or dehydrated and embedded in Spurr's, Unicryl, or LR White resin. Frozen sections and sections of acrylic-embedded tissue were immunolabeled in the MW oven with an anti-catalase antibody, followed by gold labeling. Controls were processed conventionally at room temperature (RT). The use of MWI greatly shortened the fixation, processing, and immunolabeling times without compromising the quality of ultrastructural preservation and the specificity of labeling. The higher immunogold labeling intensity was achieved after a 15-min incubation of primary antibody and gold markers under discontinued MWI at 37C. Quantification of the immunolabeling for catalase indicated a density increase of up to fourfold in the sections immunolabeled in the MW oven over that of samples immunolabeled at RT. These studies define the general conditions of fixation and immunolabeling for both acrylic resin-embedded material and frozen sections.     

Quick Staining Method For Frozen Sections

Since the advent and general acceptance of frozen sections in histological and pathological laboratories it has been necessary to devise methods for staining these sections. The usual method is fixing the tissue to a slide by the use of celloidin. This paper is an attempt to describe a permanent, quick method of staining frozen sections without distortion or mechanical tearing of the tissues.     

A new approach to improve the quality of ultrathin cryo-sections; its use for immunogold EM and correlative electron cryo-tomography

Cryo-ultramicrotomy can be used to obtain ultrathin cryo-sections from cryo-fixed or aldehyde-fixed cryo-protected vitreous biologic samples. For immuno-gold EM, cryo-sections are retrieved from the cryo-chamber on a droplet of a pick-up solution (paste-like and almost frozen) to which the sections attach. The sections are then placed on an EM specimen grid at room temperature. This procedure compromises the ultrastructure, resulting in folds, holes, and loss of the original material. In this paper we show the critical influence of humidity, stretching, and relief of compression during thawing of the sections. We show a new lift-up hinge device for semi-automated retrieval of cryo-sections that results in significantly improved section quality. This approach was also applied successfully to vitreous sections from high pressure frozen samples. An important advance is that these vitreous cryo-sections can now successfully be post-fixed and immunolabelled after thawing; this allows cryo-EM comparison with adjacent ribbons of sections still in the frozen hydrated state. These findings call for technical innovations aiming at automated cryo-ultramicrotomy in a fully controlled environment for improved localization of proteins within their 'close to native' cellular context and correlative electron cryo-tomography of consecutive ribbons of sections of one frozen hydrated sample.     

Rapid Nissl Staining for Frozen Sections of Fresh Brain

Working with X-ray film autoradiography of soluble isotopes, we needed a staining technique for the localization of nuclei in frozen sections of fresh brain. We have found no Nissl staining method in the literature concerning autoradiography specially recommended for this purpose, nor have we found in handbooks on staining a Nissl method clearly recommended for unfixed, frozen sections of brain. The methods described are intended for paraffin or celloidin sections, and require fixation of brain before sectioning (which must be avoided when working with soluble isotopes). Because autoradiography is a time-consuming method, any technique which shortens time needed for the overall procedure is welcome. Most Nissl techniques described in the literature require long preprocessing of the tissue. We found two rapid methods, described by Humason (1967) and LaBossiere and Glickstein (1976), but their application to frozen sections did not give good results. After trials with several types of techniques, we succeeded in developing two Nissl modifications with slightly different qualities, one of 12 min and the other of 2-3 h. The longer method includes conventional steps in staining; the shorter method does not include fixation or lipid extraction. These methods were applied to 20-60 μm brain sections cut in the cryostat at -10 to -12 C and dried on gelatinized slides.     

A new rapid immunohistochemical staining technique using the EnVision antibody complex.

Rapid immunohistochemical investigation, in addition to staining with hematoxylin and eosin, would be useful during intraoperative frozen section diagnosis in some cases. This study was undertaken to investigate whether the recently described EnVision system, a highly sensitive two-step immunohistochemical technique, could be modified for rapid immunostaining of frozen sections. Forty-five primary antibodies were tested on frozen sections from various different tissues. After fixation in acetone for 1 min and air-drying, the sections were incubated for 3 min each with the primary antibody, the EnVision complex (a large number of secondary antibodies and horseradish peroxidase coupled to a dextran backbone), and the chromogen (3,3'diaminobenzidine or 3-amino-9-ethylcarbazole). All reactions were carried out at 37C. Specific staining was seen with 38 antibodies (including HMB-45 and antibodies against keratin, vimentin, leukocyte common antigen, smooth muscle actin, synaptophysin, CD34, CD3, CD20, and prostate-specific antigen). A modification of the EnVision method allows the detection of a broad spectrum of antigens in frozen sections in less than 13 min. This method could be a useful new tool in frozen section diagnosis and research. (J Histochem Cytochem 49:623-630, 2001)     

A perfusion-fixation procedure for the concurrent demonstration of Timm's, horseradish peroxidase (HRP), and acethycholinesterase (AChE) histochemistry

The sulfide-silver method of Timm has been a widely used histochemical technique to demonstrate the presence of heavy metals in biological tissue, particularly in the central nervous system. However, the use of this method or its several modifications results in less than optimal morphological preservation and requires embedding the tissue in paraffin or freezing it and cutting it directly onto slides with a cryostat. These procedures can decrease the sensitivity and limit the application of other histochemical procedures, particularly when experiments necessitate processing large specimens or reaction procedures require techniques using free-floating sections. A perfusion-fixation protocol is described that yields sufficient fixation to cut whole frozen blocks of tissue with a sliding microtome, permits the use of free-floating sections, and allows the concurrent demonstration of horseradish peroxidase and acetylcholinesterase histochemistry without loss of sensitivity. The method consists of a short initial exposure to a sodium sulfide solution followed by a prolonged exposure to a combined sulfide-aldehyde fixative solution.     

Intraoperative evaluation of sentinel lymph nodes in breast cancer: comparison of frozen sections,imprint cytology and immunocytochemistry

M. Francz, K. Egervari and Z. Szollosi
Intraoperative evaluation of sentinel lymph nodes in breast cancer: comparison of frozen sections, imprint cytology and immunocytochemistry Objective: We analysed the utility of imprint cytology with rapid immunocytochemistry and frozen section analysis for the evaluation of sentinel lymph nodes in breast cancer patients. Methods: The sensitivity, specificity, and positive and negative predictive values have been calculated for each method individually, each pair and all three together. We compared these results with those of routinely processed paraffin sections. Results: The sensitivity and specificity of each of the three methods for detection of metastatic carcinoma were as follows: 69.4% and 97.8% for touch imprint cytology; 58.3% and 100% for frozen sections; 68.5% and 98.9% for rapid immunocytochemistry. When the methods were combined, the highest accuracy was achieved by touch imprint cytology, frozen sections, touch imprint cytology plus rapid immunocytochemistry, or touch imprint cytology frozen section analysis and rapid immunocytochemistry, each of these having identical sensitivity and specificity of 72.2% and 97.8%, respectively. Conclusions: In our study the combined accuracy of the three methods was the same as combining touch imprint cytology and frozen sections or touch imprint cytology plus rapid immunocytochemistry. Rapid immunocytochemistry provides an additional parameter and preserves tissue for permanent sections.     

Lead acetate as a vital marker for the analysis of bone growth

The use of lead acetate as a vital stain adds another method for the study of periodic appositional patterns of hard tissues. The distinct advantage of this technique is that these tissues can be decalcified and examined histologically without loss of the marker. The following method was used in preparation of the sections shown in the text. The rats received an intravenous injection of 4 mg lead acetate/kg body weight. After sacrifice, the tissues were decalcified in 1% HCL through which H₂S was constantly bubbled. The action of the H₂S gas is to convert the lead at sites of calcification to insoluble lead sulfide. Upon completion of decalcification the sections were embedded in 30% gelatin, and frozen sections at 15–20 μ were cut. The sections were then placed in a 0.1% solution of gold chloride for ten minutes. Next, they were placed in a 5% solution of sodium bisulphate for ten minutes. Subsequently they were washed in distilled water for 30 minutes and finally fixed in a 5% solution of sodium thiosulphate. No additional staining was used. The sections were then mounted with glycerine jelly. The resulting lead lines are sharp and therefore conducive to quantitative measurements. Because of the relatively thin sections cut, histologic details can be observed.     

Combination of lamin immunocytochemistry and in situ hybridization for the analysis of chromosome copy numbers in tumor cell areas with high nuclear density

We describe the application of lamin immunocytochemistry (ICC) and single- or double-target fluorescence in situ hybridization (FISH) on 4 microm thick frozen tissue sections as a method to facilitate scoring of aberrant chromosome copy numbers in colonic tumors. Analysis of FISH signals in colon tissue sections is often hampered by overlap and truncation of epithelial nuclei, due to the density of the epithelial cells. Furthermore, on the basis of nuclear staining it is often difficult to determine whether or not nuclei are overlapping, or adjoining. Therefore, reliable evaluation of (F)ISH signals to screen for genomic changes was until now mainly restricted to isolated nuclei obtained from relatively thick tissue sections. In this study the applicability of lamin ICC, to stain the nuclear periphery and to distinguish individual nuclei, combined with the FISH procedure is explored to solve this problem for colon epithelium. For ICC we applied the alkaline phosphatase (APase)-Fast Red detection method, since the fluorescent precipitate of this reaction resists extensive proteolytic digestion as needed for efficient FISH on tissue sections. Chromosome copy numbers could easily be determined in 4 microm thick frozen tissue sections by combining lamin ICC and FISH. The ratio of the copy numbers of the chromosomes 7 and 17 could be determined in frozen tissue sections after combined lamin ICC and double-target FISH. It is concluded that the combination of lamin ICC and FISH improves chromosome copy number analysis and can be used to investigate genomic changes in different tumor compartments in thin frozen tissue sections.     

Demonstration of surfactant phospholipids in frozen sections of the lung

Saturated phospholipids are known to be the only surface active compounds present in the surfactant system of the lung. Using light microscopy, the identification in situ of pulmonary surfactant has always been hampered by the lack of satisfactory fixatives and dyes which act on saturated phospholipids fast enough to prevent the complete loss of surfactant in the solutions. In this study we adopted the tricomplex flocculation proposed by Elbers et al. (1965) to fix surfactant phospholipids on frozen sections obtained from human, pig and rat lungs. Small pieces of lung tissue were quickly frozen in freon 22 kept at -75 C.; eight micron sections were cut in a cryostat, air dried and immersed for 30s-5m in a 0.05 N Pb(NO3)2 + K3Fe (CN)6 solution in 10% formalin. Lead ions bound to the choline portion of phospholipid molecules were subsequently revealed in a 30 mM ammonium sulfide solution. This procedure delineates a dark brown filmy structure in the respiratory parenchyma, which is very loosely attached to the alveoli and appears to be related to lung surfactant. Preliminary lung lavage or pretreatment of sections with saline, aldehyde fixatives and several organic solvents, fully or partially abolish the stain.     

The birth of mice from testicular spermatozoa retrieved from frozen testicular sections

Male gamete cryopreservation has been widely used for both human reproduction and animal breeding. We investigated whether testicular spermatozoa retrieved from frozen testicular sections (10 or 25 mum thick) could support the full-term development of normal progeny. For this purpose, frozen testicular sections were prepared from two genetic backgrounds (BDF1 or B6 GFP transgenic mice), and the functional ability of testicular spermatozoa after preservation for 1 day, 1 mo, and 3 mo was assessed by intracytoplasmic sperm injection (ICSI). Testicular spermatozoa were successfully retrieved from frozen testicular sections for the use of ICSI, regardless of the preservation period. The ICSI technique revealed that oocytes (BDF1 or B6 background) injected with testicular spermatozoa prepared from frozen testicular sections developed into normal progeny, even though the sections had been cryopreserved for 3 mo at -30 degrees C. Approximately 15% and 5% of the embryos preserved for 3 mo developed to full term if the testicular spermatozoa were prepared from the 25- and 10-mum sections, respectively. These results clearly indicate that male gametes can be viably preserved in frozen testicular sections. The technique described herein will allow the preservation of male gametes in the form of a "book" or "file" by mounting the sections on a paper-thin sheet. Furthermore, this technique may be of value in the clinical treatment of severe male infertility, since testicular spermatozoa can easily be found through examination of testicular cross sections rather than by attempts to identify them in testicular cell suspension.     

A method for preparing 2- to 50-µm-thick fresh-frozen sections of large samples and undecalcified hard tissues

This article describes a method for preparing 2- to 50-micron-thick fresh-frozen sections from large samples and completely calcified tissue samples. In order to perform the more routine work involved, a tungsten carbide disposable blade was installed to a heavy-duty sledge cryomicrotome. An entire 10-day-old rat and bone and tooth samples from a 7-month-old rat were rapidly frozen. The frozen samples were attached to the cryomicrotome stage. The cutting surface of the samples was covered with a polyvinylidene chloride film coated with synthetic rubber cement and cut at -25 degrees C. The soft tissues and the hard tissues were satisfactorily preserved and all tissue cells were easily identifiable. Enzymatic activity in the fresh sections was much stronger than that in chemically fixed and/or decalcified sections. The sections permitted histological and histochemical studies without trouble. In addition, the sections can be used for multiple experiments such as immunohistochemistry, in situ hybridization, and electron microprobe X-ray micro-analysis. This method can be used with conventional cryomicrotome equipment.     

A Bodian method for mounted frozen sections.

For application of the Bodian method to frozen sections, cut frozen peripheral nerve or muscle at 10 mum and mount. Fix for 4 days in 18 parts 80% ethanol, 1 part 10% formalin, and 1 part glacial acetic acid. Fix central nervous tissue in the same mixture prior to freezing and sectioning, and after mounting postfix for 4 days. Impregnate by the Bodian procedure. The results equal Bodian stains of paraffin sections. The technique is simple and reliable. The use of 10 mum frozen sections produces little artifact and allows alternate serial sections to be stained with other techniques.