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Hewer's Textbook of Histology for Medical Students -  S. Bradbury

Hewer's Textbook of Histology for Medical Students (eBook)

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2014 | 9. Auflage
478 Seiten
Elsevier Science (Verlag)
978-1-4831-6349-9 (ISBN)
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Hewer's Textbook of Histology for Medical Students, Ninth Edition Revised focuses on the minute structure of the cells, tissues, and organs of the human body and the reactions of tissues and cells to various conditions. The publication first elaborates on the techniques used in the study of cells and tissues, cell and cell division, and epithelia. Discussions focus on the qualitative and quantitative methods for the identification of the composition of cells and tissues, surface membrane of the cell, cytoplasmic contents, and the nucleus. The text then examines blood and lymph, development and destruction of blood corpuscles, and connective tissues. The manuscript takes a look at adipose tissue, cartilage, and bone, including development and functions of adipose tissue, hyaline cartilage, fibro-cartilage, elastic cartilage, and joints and synovial membranes. The book then ponders on muscular tissue, nervous tissue, peripheral nerves, ganglia, neuroglia, and meninges, blood circulatory system, lymphatic system, thymus, and spleen, and adrenals, thyroid, and parathyroid glands. The publication is a valuable reference for medical students and readers interested in the structure of the cells, organs, and tissues of the human body.
Hewer's Textbook of Histology for Medical Students, Ninth Edition Revised focuses on the minute structure of the cells, tissues, and organs of the human body and the reactions of tissues and cells to various conditions. The publication first elaborates on the techniques used in the study of cells and tissues, cell and cell division, and epithelia. Discussions focus on the qualitative and quantitative methods for the identification of the composition of cells and tissues, surface membrane of the cell, cytoplasmic contents, and the nucleus. The text then examines blood and lymph, development and destruction of blood corpuscles, and connective tissues. The manuscript takes a look at adipose tissue, cartilage, and bone, including development and functions of adipose tissue, hyaline cartilage, fibro-cartilage, elastic cartilage, and joints and synovial membranes. The book then ponders on muscular tissue, nervous tissue, peripheral nerves, ganglia, neuroglia, and meninges, blood circulatory system, lymphatic system, thymus, and spleen, and adrenals, thyroid, and parathyroid glands. The publication is a valuable reference for medical students and readers interested in the structure of the cells, organs, and tissues of the human body.

CHAPTER 1

SOME TECHNIQUES USED IN THE STUDY OF CELLS AND TISSUES


Publisher Summary


This chapter discusses a few techniques used in the study of cells and tissues, including phase contrast and interference microscopy and electron microscopy. The great advantage of phase contrast microscopy is that it introduces contrast by optical means into unstained preparations of transparent objects. In the electron microscopy method, the energy source is a beam of electrons emitted from an electrically heated tungsten cathode situated at the top end of a tube in which a vacuum is constantly maintained by means of a series of pumps. The great advantage of the electron microscope lies in its far greater resolving power as compared with the optical microscope. The resolving power of the latter, that is, its ability to image two small objects close together so that they appear separate and not as one, is a function both of the numerical aperture of the objective and of the wavelength of light. Because of the very poor penetrating power of electrons, very thin slices of tissue have to be used in electron microscopy.

Many new methods for the study of histology have been developed during the last fifteen or twenty years. Some of these have such a wide application and are producing such important and interesting results that it is necessary for the student to be acquainted at least with the principles underlying them. The following is a brief account of the more important among them.

A Methods of Looking at Cells


(1) Phase Contrast and Interference Microscopy.

The need to study living cells is becoming increasingly important and the conventional optical microscope has severe limitations in this respect, as indeed, has the human eye. Most living cells are virtually transparent objects whose constituent parts differ but little from one another in refractive index, so that there is hardly any visible contrast between them. Moreover, the refractive index of most living cells is very close to that of the aqueous media in which they are likely to be placed for microscopical examination. In consequence living cytoplasm appears structureless and empty to a large degree. This is, of course, one of the reasons why, in the past, so much use was made of cells that had been chemically treated (fixed) and coloured with various dyes, because this method revealed structures that could not be seen in the living cell. It was often open to question, however, whether such structures were artifacts of the technique rather than objects actually present. The great advantage of phase contrast microscopy is that it introduces contrast by optical means into unstained preparations of transparent objects e.g. living cells. A mathematical treatment of the theory of phase contrast is complex, but the following general account will serve to introduce the principle of the method.

When light passes through a transparent object which is mounted in a medium which differs in refractive index from itself, it does so with no change in the amplitude of the light waves. Since the retina of the eye is sensitive only to amplitude changes the object is therefore virtually invisible. Although there has been no change in the amplitude of the transmitted light it has nevertheless been affected by its passage through the object. Diffraction generates a set of new waves which differ in phase from the direct light which has not passed through the object (Fig. 1.1). This change in the phase of the diffracted light is of the order of a quarter of a wavelength (½λ) for a typical cell.

FIG. 1.1 A diagram of the effect of a transparent object on light. The waves which have passed through it are retarded in phase by about ¼λ with respect to the original beam but their amplitude is unchanged.

The microscope image is formed as a result of interference between the direct light and the light diffracted by the object, so that if the phase difference between these two sets of waves can be further increased by optical means until the total difference between them is about ½λ, then maximal destructive interference will result. There will thus be formed amplitude differences which can be recognized by the eye. The transparent object on the stage of the microscope thus is seen as if it were an absorbing object and it appears dark to a greater or lesser degree, depending on the amount of phase change which it has introduced into the diffracted light.

The practical problem, clearly, is to devise an optical system whereby the incident and diffracted waves are separated and the phase difference between them increased by ½λ. This was achieved many years ago by Zernike but the significance of his discovery was not immediately appreciated by biologists.

Fig. 1.2A shows the optical system of the phase contrast microscope. An opaque diaphragm (A) containing a transparent annulus is placed at the back focal plane of the substage condenser (C). Direct light, unaffected by the object on the stage at S, will form an image of the annulus in the back focal plane of the objective (O); the diffracted light which appears to emanate from the object will, however, be evenly spread over the same area. Inside the objective a transparent phase plate (P) which has a circular groove in it is mounted so that the direct image of the annulus (A) coincides exactly with the groove.

FIG. 1.2A (top) The principle of the phase-contrast microscope; A represents the illuminating annulus, C the condenser, S the plane of the specimen, O the microscope objective lens and P the phase plate situated in the back focal plane of the objective. The path of the diffracted light is shown dotted, that of the direct light in a full line.

The diffracted light will pass through the full thickness of the phase plate both inside and outside the groove, whilst the direct light passes through the thinner area occupied by the groove. The extra thickness of the glass (x in Fig. 1.2B) that the diffracted light has to traverse is so calculated that it introduces a further ¼λ phase change relative to the direct light. The resulting destructive interference will produce a final image in which considerable detail can be seen (e.g. nucleus, chromosomes, mitochondria, lipid droplets, etc.). Fig. 1.3 shows the appearance of a living fibroblast visualized by phase contrast microscopy.

FIG. 1.2B (below) A diagram of the phase plate in the objective. Note that the direct light all passes through the groove in the plate, whilst the diffracted light suffers a further retardation by having to pass through the extra thickness “x”.

FIG. 1.3 A living fibroblast in culture photographed with the phase contrast microscope. Note the “halo” around the cell border and the high contrast of the cytoplasmic inclusions. The mitochondria may be seen as long filamentous objects.

When a living cell is immersed in a medium whose refractive index is the same as its own it shows minimum contrast, that is it becomes invisible in the phase microscope. Now, many cells will survive quite well in osmotically-balanced aqueous solutions of proteins such as bovine plasma albumin and it is not difficult to find, by trial and error, that solution of known concentration which causes a particular cell (e.g. an erythrocyte, a fibroblast, etc.) to become virtually invisible when immersed in it.

Under these conditions the concentration of protein in the mounting medium will be approximately equal to that of the proteins in the cell. Since, in some cells, there may be significant amounts of other substances (e.g. carbohydrates) in addition to protein, more precisely the value obtained indicates the concentration of protoplasmic solids. Where this method of cell refractometry has been used the results have been in good agreement with those obtained by using other and quite different methods. Phase contrast microscopy has the great advantage that high contrast images of living cells can be achieved easily and with relatively simple equipment; because of the incomplete separation of direct and diffracted light, however, the image suffers from certain defects, especially from the presence of a marked “halo” around the edges where there is a sharp difference in refractive indices.

Like the phase contrast microscope, the interference microscope may be used qualitatively to provide contrast in transparent objects and quantitatively to obtain information about the concentration of substances in cells and in addition to measure cell dry mass. In all types of interference microscope a beam of coherent light (i.e. light from a single source) is split in such a way that one part of the beam passes through the specimen and the other passes to the side of it. The light which bypasses the object is called the reference beam. Before entering the objective lens the two beams are recombined by a special system called a beam recombiner. One type of system is so arranged that the field of view has distributed across it a series of parallel dark interference bands, each band representing a zone of maximum destructive interference between the two beams at recombination. Where there is no object in the field the interference bands are evenly spaced and are separated by intervals...

Erscheint lt. Verlag 24.4.2014
Sprache englisch
Themenwelt Medizin / Pharmazie Medizinische Fachgebiete Chirurgie
Studium 1. Studienabschnitt (Vorklinik) Anatomie / Neuroanatomie
Naturwissenschaften Biologie Humanbiologie
ISBN-10 1-4831-6349-0 / 1483163490
ISBN-13 978-1-4831-6349-9 / 9781483163499
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