Affixing Polyester Wax Sections to Glass Slides by Celloidin and Cellulose Acetate Applied in Sequence

Sections cut from material embedded in polyester wax can be firmly attached as follows: One drop of a 2% solution of celloidin in amyl acetate is smeared on clean slides, and sections taken from the floatation water onto these slides are dried at room temperature. After drying the slides are immersed in a 2% solution of cellulose acetate in acetone for 1 min, transferred directly to absolute ethanol, through 50% ethanol, and into water. Sections affixed by this method and stained by either hematoxylin-eosin or toluidine blue schedules do not loosen and have negligible background staining.     

Mounting Frozen Sections with Gelatin

Frozen sections, 15-50 µ thick, are soaked for 5 minutes or longer in a mixture of equal parts of 1.5% aqueous gelatin and 80% alcohol, and teased onto a slide. After allowing excess fluid to evaporate, sections will be moist and can be blotted with filter paper that may require dampening with 95% alcohol. Immersed in 95% alcohol, the remaining gelatin will congeal, anchoring the section to the slide. If necessary, the sections can subsequently be coated with celloidin.     

A Durable Nissl Stain for Frozen and Paraffin Sections

Frozen sections, 25-50 /j. thick, of formalin-fixed nervous tissues are mounted following the Albrecht gelatin technic. Paraffin sections, 15 p., are deparaffinized and transferred to absolute ethanol. The slides are then coated with celloidin. Both frozen and paraffin sections subsequently follow the same steps: absolute ethanol-chloroform (equal parts) for at least 20 min, 95% ethanol, 70% ethanol (1-3 min), then rinsed in distilled water. Sections are stained in Cresylechtviolett (Chroma) 0.5% aqueous solution containing 4 drops of glacial acetic acid per 100 ml, rinsed in distilled water, agitated in 70% ethanol until excess stain leaves the slide, and rinsed in 95% ethanol. Sections are then dehydrated in absolute ethanol, followed by butanol, cleared in xylene, and enclosed in permount.     

Staining method for whole-body autoradiography.

Sagittal whole-body sections of frozen mice were cut on a hydraulicly driven microtome in a cryostat at--15 C by applying cotton or nylon-backed adhesive tape to the mouse before cutting. Section thickness was 20 mu. The sections, still adhering to the tape, were dried in the cryostat (-15C) under atmospheric pressure. After autoradiography, the sections were pressed to a glass slide spread with a mixture of albumin and glycerin. The slide was immersed in xylene at 30 C for 15 min. The tape was then removed from the slide, where the section remained to be stained with hematoxylin-eosin. The section thus obtained enabled the tissue histology to be related to the autoradiogram. This method may also be applied to histochemical studies of substances insoluble in xylene.     

Deplasticizing of thick Epon sections involving a new adhesive technique and staining of nervous tissue

The present communication deals with a technique developed for the selective staining of neural tissue in thick (10 micron) Epon sections. A new adhesive method was needed, because the known techniques are only applicable to 0.5-2 micron thin sections. The critical step in the procedure is the adhesion of the sections onto the slides. This is accomplished by heating the sections on top of a uniform layer of albumin glycerol on the slide followed by coating with celloidin. The results after deplasticizing and coagulation with this technique are comparable to those obtained by paraffin or frozen section techniques, but in addition have the advantage of Epoxy resin embedding e.g. the possibility of cutting undecalcified hard tissues and sections for serial reconstruction.     

Autoradiography of Mobile,C14-Labeled Herbicides in Sections of Leaf Tissue

Fresh leaf tissue containing a soluble, C¹⁴-labeled herbicide was mounted in cold 1% gelatin on a holder, quick frozen in a cryostat, and cross sectioned at 16 μ with single-edge, stainless steel razor blades. The sections were transferred (without thawing) to cold (—10 C) microscope slides which had been partly covered with double-coated Scotch tape #665. The tissue was freeze-dried in a vacuum desiccator at—20 C then secured to the tape with pressure. Autoradiography was accomplished in a darkroom by covering the slides with dry, nuclear track emulsion films. These films were made by dipping 2 inch diameter wire loops into liquid emulsion, letting the film dry, and applying it by blowing it as it was placed against the tissue. After a 19 day exposure in light-tight boxes at 25-27 C the preparations were processed in the usual manner. The method-was used successfully to trace the movement of soluble, C¹⁴-labeled herbicides in leaf tissue without the loss of labeling material or artifacts caused by its diffusion. High resolution autoradiograms with low backgrounds were obtained.     

Scanning Electron Microscopy of Pine Seedling Wood Tissue Sections Inoculated with the Pinewood Nematode Bursaphelenchus xylophilus Previously Prepared for Light Microscopy

Scanning electron microscopy (SEM) was applied to paraffin-embedded wood sections to study the histopathology of pine seedlings inoculated with the pinewood nematode (PWN), Bursaphelenchus xylophilus. The sections, which had been previously prepared and observed by light microscopy (LM) on glass slides, were originally obtained from experiments in which pine seedlings had been inoculated with PWN. The cover glass was removed by soaking the glass slide in xylene for 3 to 5 days. The glass slides were cut into small pieces so that each piece contained one wood section. Each piece of the glass slide was attached with double adhesive tape to an aluminum stub. The specimens were sputter-coated with gold and examined with a scanning electron microscope (JEOL-JSM 5200). Compared to LM (as documented in previous reports) SEM provided greater depth of focus and resolution of the damaged wood tissues, nematodes and associated bacteria. SEM made it possible to observe the relationship between bacterial distribution and nematode distribution in wood tissues. SEM observations also suggested the possibility of documenting the death of ray cells and other parenchyma cells in relation to disease development. Finally, the current study of PWN in pine seedlings demonstrated that glass slides prepared for LM observations more than 25 years earlier could be successfully processed for examination by SEM.     

A method for preparing whole-body sections suitable for autoradiographic, histological and histochemical studies

A method for the preparation of whole-body sections suitable for autoradiographic and histochemical study is described. Radioactive calcium chloride or [14C]proline was injected into the abdominal cavity of a rat. Thirty-five minutes after injection of calcium chloride or 40 min after injection of proline the rat was frozen in a mixture of hexane and solid carbon dioxide and blocked in 5% sodium carboxymethyl cellulose. The carboxymethyl cellulose block was trimmed and a piece of copy paper was attached to the surface of the block with cellulose tape. Cryotome sections cut from the block were transferred from the paper to a glass slide coated with synthetic rubber adhesive. For whole-body autoradiography, sections were freeze-dried for 2 days and then placed against X-ray film. For light microscopic autoradiography, the freeze-dried sections were covered with a dried film of photographic emulsion. For histochemical use, the sections were fixed by raising the temperature to 4 C after immersion in 100% ethanol below -10 C. For histological observation, sections were postfixed with 2.5% glutaraldehyde and stained. Whole-body and light microscopic autoradiographs showed that sections so prepared could be used for the demonstration of soluble substances in whole-body sections and for detailed autoradiography at the light microscopic level, and the stained sections could be used for histological and histochemical studies.     

A Method for Preparing Whole-Body Sections Suitable for Autoradiographic, Histological and Histochemical Studies

A method for the preparation of whole-body sections suitable for autoradiographic and histochemical study is described. Radioactive calcium chloride or [¹⁴Clproline was injected into the abdominal cavity of a rat. Thirty-five minutes after injection of calcium chloride or 40 min after injection of proline the rat was frozen in a mixture of hexane and solid carbon dioxide and blocked in 5% sodium carboxymethyl Cellulose. The carboxymethyl cellulose block was trimmed and a piece of copy paper was attached to the surface of the block with cellulose tape. Cryotome sections cut from the block were transferred from the paper to a glass slide coated with synthetic rubber adhesive. For wholebody autoradiography, sections were freeze-dried for 2 days and then placed against X-ray film. For light microscopic autoradiography, the freeze-dried sections were covered with a dried film of photographic emulsion. For histochemical use, the sections were fixed by raising the temperature to 4 C after immersion in 100% ethanol below -10 C. For histological observation, sections were postfixed with 2.5% glutaraldehyde and stained. Wholebody and light microscopic antoradiographs showed that sections so prepared could be used for the demonstration of soluble substances in wholebody sections and for detailed autoradiography at the light microscopic level, and the stained sections could be used for histological and histochemical studies.     

Semipermanent microscope slides of microfungi using a sticky tape technique

A technique is described for making semipermanent microscope slides of fungi using sticky tape. After being touched to a fungal colony, a modified segment of sticky tape is touched to ethyl alcohol and then immersed in a 50% glycerine solution containing cotton blue stain. Finally, it is transferred (sticky side up) to a microscope slide, covered with a cover with a cover glass, and sealed.     

Squashing Under Scotch Tape No. 665 for Autoradio-Graphic and Permanent Histologic Preparations

Removal of the cover slip from squash preparations, for coating with auto-radiographic emulsion, or other purposes, is made easy if squashing is performed with a piece of Scotch double-coated adhesive tape No. 665, used as a cover slip. The material to be squashed is placed on a slide lightly coated with an adhesive consisting of 1% gelatin with 0.1% chrome alum added. The piece of tape is applied with the surface originally on the outside of the roll next to the specimen. Specimens should be soaked before squashing in aqueous 45% acetic acid, with or without added dye, such as carmine or orcein. After squashing, the tape is easily removed without damage to the cells. This allows autoradiographic emulsion to be applied, or, unstained material can be stained after squashing by technics suitable for microtome sections.     

A Plastic-Seal Method for Mounting Sections of Ground Bone

If sections of ground bone are first coated with a plastic solution before applying the usual mounting medium and a cover glass, excellent optical differentiation results. The solution consists of 28 g. of Parlodion dissolved in 250 ml. of either butyl or amyl acetate. Bone sections are prepared by grinding to the desired thinness, dehydrated with alcohol, air dried, dipped in the solution, freed of surface bubbles by agitation, and placed on a slide. After allowing the preparation to dry thoroughly, the customary mounting medium and cover glass are applied. The plastic seal prevents the escape of air from the lacuni and canaliculi, preserves the natural differentiation of bone tissue, and also permits it to be viewed with a polarizing microscope.     

Plastic Embedding, Orientation in the Mold and Tape-Supported Sectioning of Sclerotized Insects and Other Hard Objects

Sections of large specimens such as whole honeybees or beetle adults embedded in plastic usually are difficult to cut with a constant thickness. The sections also compress and roll. Sections of even thickness have been obtained by using a mixture of methacrylates (ethyl, 1:butyl, 3) and by firmly supporting the block in the microtome with a special holder. Scotch tape #810 applied to the block before each section is cut eliminates section compression and rolling. The sections are attached to slides with 2% celloidin in an absolute alcohol-methyl benzoate mixture (5:5-7:3); and the tape is removed with heptane. Large sections can also be cut from blocks of styrene mixed with butyl methacrylate. The specimens are oriented in the monomer in gelatin capsules by directing them into the desired plane among the fibers of a wad of absorbent cotton previously placed in the bottom of the capsule. The cotton is sectioned with the specimen but its fibers do not interfere, and remain outside the tissue.     

Autoradiography of Mobile, C14-Labeled Herbicides in Sections of Leaf Tissue

Fresh leaf tissue containing a soluble, C¹⁴-labeled herbicide was mounted in cold 1% gelatin on a holder, quick frozen in a cryostat, and cross sectioned at 16 μ with single-edge, stainless steel razor blades. The sections were transferred (without thawing) to cold (—10 C) microscope slides which had been partly covered with double-coated Scotch tape #665. The tissue was freeze-dried in a vacuum desiccator at—20 C then secured to the tape with pressure. Autoradiography was accomplished in a darkroom by covering the slides with dry, nuclear track emulsion films. These films were made by dipping 2 inch diameter wire loops into liquid emulsion, letting the film dry, and applying it by blowing it as it was placed against the tissue. After a 19 day exposure in light-tight boxes at 25-27 C the preparations were processed in the usual manner. The method-was used successfully to trace the movement of soluble, C¹⁴-labeled herbicides in leaf tissue without the loss of labeling material or artifacts caused by its diffusion. High resolution autoradiograms with low backgrounds were obtained.     

蛋白质微阵列生产用琼脂糖修饰玻片制备的条件优化

目的:建立一种以琼脂糖修饰的玻片为载体的蛋白质微阵列制备的优化方法,比较琼脂糖修饰玻片和醛基修饰玻片及氨基修饰玻片对蛋白质固定效率的优劣。方法:将羊IgG固定在载体表面,经过洗涤、封闭,再加入Cy3标记的兔抗羊IgG,孵育,洗涤后用共聚焦激光扫描仪获取图像,检测各点的荧光强度,根据荧光强度确定最佳琼脂糖浓度,最佳NaIO4浓度,最佳固定时间以及封闭时间等实验条件。结果:琼脂糖浓度为1.2％、NaIO4浓度为20mmol／L、固定时间为1h、孵育时间为45min时,蛋白质在载体上的固定效率和反应活性最高。在固定的抗体浓度相同的情况下,琼脂糖修饰玻片荧光强度是醛基修饰玻片的2.6倍,是氨基修饰玻片的9倍。结论:确立了蛋白质微阵列生产用琼脂糖修饰玻片制备的优化条件,用该优化条件制备的琼脂糖玻片更适合用于蛋白质微阵列载体。     

Basic Dye Counterstaining of Sections Impregnated by the Golgi-Cox Method

Celloidin blocks of Golgi-Cox impregnated material are cut at 50 μ, the sections collected in 70% alcohol, transferred to a 3:1 mixture of absolute alcohol and chloroform for 2 min, and then stored in xylene or toluene for at least 3 min, or up to 2 wk until processed further. Mounting is done on glass slides which have been coated with fresh egg albumen diluted in 0.2% ammonia water (or a 0.5% solution of dry powdered egg albumen) and then dried at 60°C overnight. For attachment to these coated slides, sections are first soaked for 2-3 min in a freshly prepared mixture of methyl benzoate, 50 ml; benzyl alcohol, 200 ml; chloroform, 150 ml; and then transferred quickly to the slides by means of a brush. After 2-3 min the chloroform evaporates and the celloidin softens. The slides are then immersed in toluene which hardens the celloidin and anchors the sections to the slides. Alcohols of descending concentrations to 40% are followed by alkalinizations, first in: absolute alcohol, 40 ml; strong ammonia water 60 ml, for 2 min, then in: absolute alcohol, 70 ml; strong ammonia water, 30 ml, for 1 hr. Excess alkali is then removed by 70% and 40% alcohol, 2 min each, and a 10 min wash in running tap water. Bleaching in 1% Na₂S₂O₃, for 10 min and washing again in tap water for 10 min completes the process preliminary to staining. The preparations are then stained for 90 min in an aqueous solution of either 0.5% cresylecht violet, neutral red, or Darrow red, buffered at pH 3.6. Dehydration and differentiation in ascending grades of alcohol, clearing with toluene or xylene, and applying a cover glass with a mounting medium having a refractive index of about 1.61 completes the process.     

DNA微阵列基片的化学处理

对于合成后点样的DNA微阵列 ,基片的表面化学处理非常重要。它直接影响到样品与基片的结合效率 ,进而影响杂交结果。基片表面的各种化学修饰方法多种多样 ,物理吸附主要以赖氨酸包被为主。共价结合通常使用同源偶联分子或异源偶联分子 ,还可以在基片表面组装线状、分支状连接分子或包被琼脂糖。着重介绍了DNA微阵列的制备 ,即样品如何固定到玻璃基片上。总结了不同类型基片表面的化学修饰方法以及DNA与基片的化学结合。     

A Sudan Black B Myelin Stain for Peripheral Nerves

Blocks of fresh issue were fixed 2 or more days in: cobalt sulfate (or nitrate), 1 gm; distilled water, 80 ml; 10% calcium chloride, 10 ml; and formalin, 10 ml. The fixed tissue was washed thoroughly in tap water, embedded in gelatin, frozen sections cut, and mounted on slides with gelatin adhesive. The sections were stained 15-30 min in a saturated, filtered solution of Sudan black B in 70% alcohol, differentiated in 50% alcohol under microscopic observation, and a cover glass applied with glycerol-gelatin. In thick (50-100 μ) sections, myelin stained green to gray-green and this allowed easy differentiation between nerves and other tissue elements.     

A gelatin film procedure for the localization of proteolytic activity in Leucochloridiomorpha constantiae (Trematoda) adults

A gelatin film procedure was used to localize proteolytic activity in the lumen of the intestinal ceca of Leucochloridiomorpha constantiae (Trematoda) adults. Slides were coated with a 7·5% gelatin solution and then fixed in 10% neutral buffered formalin (NBF). Cryostat sections of isolated worms or those attached to the bursa of Fabricius of the domestic chick were affixed to the gelatin film. Experimental and control slides were incubated in a humid chamber for 30 min at 37·5 and 4°C, respectively. Slides were again fixed in NBF, and then stained for protein with mercuric bromphenol blue (MBB). In experimental slides, the lumen of the intestinal ceca was lysed and did not stain, whereas worm and host tissue and the gelatin were protein-positive. Control sections stained uniformly positive for protein. In this procedure tissue is retained on the slide and proteolytic activity can be correlated with a tissue site on the same slide.     

Locating Iodine in Tissues Autographically, Especially after Fixation by Freezing and Drying

The ability of radioactive elements to affect photographic emulsions enables the detection of radioactive iodine in the thyroid. By placing unstained histological sections of a thyroid (from an animal treated with radioactive iodine) in contact with the gelatin side of medium lantern slide plates, each accumulation of radioactive iodine in the section affects the photographic plate. After exposures prolonged for several days to several weeks depending on the amount of radioactivity in the tissues, the plate is developed and fixed by routine photographic methods. The histological section is stained and may be compared under the microscope to the reactions on the plate or “autographs”.

In an attempt to detect the location of the inorganic iodine which is displaced during fixation and embedding by ordinary methods because of its solubility, a simplified freezing-drying technic for fixation was devised which, at least with the thyroid, yielded well fixed sections. The quick freezing was obtained with acetone-dry-ice mixtures; and the drying was performed at -25° to -30° C. Preliminary addition of paraffin to the tube in which the drying was performed made possible the inclusion in vacuum by heating the tube when drying was completed. The tissue could then be sectioned at 10ju on the microtome. The slides were placed on photographic plates for detection of radioactive iodine as indicated above. Before staining, the sections were treated with absolute alcohol for denaturation of the proteins.