Archives of Histology and Cytology 

About: Archives of Histology and Cytology is an academic journal. The journal publishes majorly in the area(s): Golgi apparatus & Endoplasmic reticulum. It has an ISSN identifier of 0914-9465. It is also open access. Over the lifetime, 2646 publications have been published receiving 40493 citations.

Use of a new adhesive film for the preparation of multi-purpose fresh-frozen sections from hard tissues, whole-animals, insects and plants.

Abstract: A method for preparing thin fresh-frozen sections from large samples and hard tissues is described and the applications are shown. A new adhesive film is introduced to produce the frozen sections. The sample is frozen in a cooled hexane or liquid nitrogen, and then freeze-embedded with 4-5% carboxymethyl cellulose (CMC) in the coolant. A specially prepared adhesive film is fastened to the cut surface of the sample in order to support the section and cut slowly with a disposable tungsten carbide blade. The adhesive film is made of a thin plastic film and an adhesive before use. This method produces 2-microm thick fresh-frozen sections from a large sample, bone or tooth. The "film-section" i.e. the section attached to the adhesive film, can be used for many types of studies such as histology, general histochemistry, enzyme histochemistry, immunohistochemistry, in situ hybridization, elemental analysis, and autoradiography for water-soluble materials. Immunohistochemistry and in situ hybridization can be carried out with nonfixed and undecalcified sections. The section on the adhesive film can be transferred to a glass slide and mounted under a cover slip, and stained sections can be examined with an optical microscope at high magnification. This method is also useful for preparing frozen sections from samples of fish, insects, and plants. Furthermore, samples of particular areas can be collected from the film-section by means of a laser microdissection technique. The multiple possible applications of the adhesive film render it highly useful for studies in biological and medico-dental fields.

Differential staining of collagens type I, II and III by Sirius Red and polarization microscopy.

Abstract: Organs of fish, amphibian, reptile, bird and mammals when stained by Sirius Red and studied with polarization microscopy present different colors in regions where collagens I, II and III have been described. Collagen type I presented a yellow, orange or red color while collagen type III appeared green. Collagen type II, present in cartilage and chondrosarcoma showed a variable color according to the tissue and the species. Its color and morphology however always permitted its clear distinction from collagens type I and type III.

Collagen fibers, reticular fibers and elastic fibers. A comprehensive understanding from a morphological viewpoint.

Abstract: Fibrous components of the extracellular matrix are light-microscopically classified into three types of fibers: collagen, reticular and elastic. The present study reviews the ultrastructure of these fibrous components as based on our previous studies by light, electron, and atomic force microscopy. Collagen fibers present a cord- or tape-shape 1-20 microm wide and run a wavy course in tissues. These fibers consist of closely packed thin collagen fibrils (30-100 nm thick in ordinary tissues of mammals), and exhibit splitting and joining in altering the number of the fibrils to form a three-dimensional network as a whole. Individual collagen fibrils (i.e., unit fibrils) in collagen fibers have a characteristic D-banding pattern whose length is ranges from 64 to 67 nm, depending on tissues and organs. During fibrogenesis, collagen fibrils are considered to be produced by fusing short and thin fibrils with tapered ends. Reticular fibers are usually observed as a delicate meshwork of fine fibrils stained black by the silver impregnation method. They usually underlie the epithelium and cover the surface of such cells of muscle cells, adipose cells and Schwann cells. Electronmicroscopically, reticular fibers are observed as individual collagen fibrils or a small bundle of the fibrils, although the diameter of the fibrils is thin (about 30 nm) and uniform. Reticular fibers are continuous with collagen fibers through the exchange of these collagen fibrils. In silver-impregnated specimens, individual fibrils in reticular fibers are densely coated with coarse metal particles, probably due to the high content of glycoproteins around the fibrils. Elastic fibers and laminae are composed of microfibrils and elastin components. Observations of the extracted elastin have revealed that elastin components are comprised of elastin fibrils about 0.1-0.2 microm thick. Elastic fibers and laminae are continuous with networks and/or bundles of microfibrils (or oxytalan fibers), and form an elastic network specific to individual tissues. The fibrous components of the extracellular matrix are thereby morphologically categorized into two systems: the collagen fibrillar system as a supporting framework of tissues and cells, and the microfibrilelastin system for uniformly distributing stress to maintain the resilience adapted to local tissue requirements.

A new drying method of biological specimens for scanning electron microscopy: the t-butyl alcohol freeze-drying method.

Abstract: A simple drying method for biological materials for scanning electron microscopy was developed. Fixed specimens were immersed in t-butyl alcohol after dehydration through a graded series of ethanol. When the room temperature fell below the melting point of t-butyl alcohol (25.5°C), liquidized alcohol obtained by warming was used. Specimens in the alcohol were then frozen in a refrigerator. They were placed in the bell jar of a vacuum evaporator and simply evacuated with a rotary pump. The samples were completely dried within 1h after the frozen alcohol was sublimated in the vacuum. When examined by scanning electron microscopy (SEM), both surface and intracellular structures were demonstrated in three-dimension without any significant drying artifacts. Careful comparison of the results indicated that the SEM images obtained by this method were either superior or equal to those obtained by the critical point drying method.

Role of stromal-epithelial interactions in hormonal responses.

Abstract: Steroid sex hormones (17beta-estradiol, testosterone, dihydrotestosterone, and progesterone) and aryl hydrocarbons such as the dioxins regulate epithelial proliferation and secretory protein production and differentiation in their respective target organs in male and female urogenital tracts and mammary glands. Recent evidence has demonstrated that stromal-epithelial interactions are critical for mediating the effects of these molecules on epithelial cells. Our results have indicated that estradiol, testosterone, progesterone, and dioxin regulate epithelial proliferation (stimulation or inhibition) via paracrine mechanisms requiring the appropriate receptor in the stroma. The androgen receptor (AR), estrogen receptor alpha (ERalpha), progesterone receptor (PR), or aryl hydrocarbon receptor (AhR) in the epithelium are neither necessary nor sufficient for the regulation of epithelial proliferation. Moreover, during prostatic development, signaling through the stromal AR is required to induce prostatic epithelial identity, ductal morphogenesis and glandular differentiation. Epithelial functional differentiation is regulated in the prostate, uterus, and vagina via AR (prostate) and ERalpha(uterus and vagina). In these organs both epithelial and stromal steroid receptors are required for steroidal regulation of certain aspects of epithelial differentiation such as epithelial secretory protein production in the uterus and epithelial cornification in the vagina and prostate (squamous metaplasia). The mechanistic basis of these stromal-epithelial interactions is poorly understood, but growth factors appear to be mediators of these cell-cell interactions.