fbpx
Wikipedia

Histology

May 12, 2023

"Histography" redirects here. For the study of history as a science, see Historiography.

Histology,[help 1] also known as microscopic anatomy or microanatomy,[1] is the branch of biology that studies the microscopic anatomy of biological tissues.[2][3][4][5] Histology is the microscopic counterpart to gross anatomy, which looks at larger structures visible without a microscope.[5][6] Although one may divide microscopic anatomy into organology, the study of organs, histology, the study of tissues, and cytology, the study of cells, modern usage places all of these topics under the field of histology.[5] In medicine, histopathology is the branch of histology that includes the microscopic identification and study of diseased tissue.[5][6] In the field of paleontology, the term paleohistology refers to the histology of fossil organisms.[7][8]

Histologic specimen being placed on the stage of an optical microscope.
Human lung tissue stained with hematoxylin and eosin as seen under a microscope.

Biological tissues

Animal tissue classification

Main article: Anatomy § Animal tissues

There are four basic types of animal tissues: muscle tissue, nervous tissue, connective tissue, and epithelial tissue.[5][9] All animal tissues are considered to be subtypes of these four principal tissue types (for example, blood is classified as connective tissue, since the blood cells are suspended in an extracellular matrix, the plasma).[9]

Plant tissue classification

 
Histologic section of a plant stem (Alliaria petiolata).
Main article: Plant Anatomy

For plants, the study of their tissues falls under the field of plant anatomy, with the following four main types:

Medical histology

Histopathology is the branch of histology that includes the microscopic identification and study of diseased tissue.[5][6] It is an important part of anatomical pathology and surgical pathology, as accurate diagnosis of cancer and other diseases often requires histopathological examination of tissue samples.[10] Trained physicians, frequently licensed pathologists, perform histopathological examination and provide diagnostic information based on their observations.

Occupations

The field of histology that includes the preparation of tissues for microscopic examination is known as histotechnology. Job titles for the trained personnel who prepare histological specimens for examination are numerous and include histotechnicians, histotechnologists,[11] histology technicians and technologists, medical laboratory technicians, and biomedical scientists.

Sample preparation

Most histological samples need preparation before microscopic observation; these methods depend on the specimen and method of observation.[9]

Fixation

Main article: Fixation (histology)
 
Histologic section of a fossilized invertebrate. Ordovician bryozoan.

Chemical fixatives are used to preserve and maintain the structure of tissues and cells; fixation also hardens tissues which aids in cutting the thin sections of tissue needed for observation under the microscope.[5][12] Fixatives generally preserve tissues (and cells) by irreversibly cross-linking proteins.[12] The most widely used fixative for light microscopy is 10% neutral buffered formalin, or NBF (4% formaldehyde in phosphate buffered saline).[13][12][9]

For electron microscopy, the most commonly used fixative is glutaraldehyde, usually as a 2.5% solution in phosphate buffered saline.[9] Other fixatives used for electron microscopy are osmium tetroxide or uranyl acetate.[9]

The main action of these aldehyde fixatives is to cross-link amino groups in proteins through the formation of methylene bridges (-CH2-), in the case of formaldehyde, or by C5H10 cross-links in the case of glutaraldehyde. This process, while preserving the structural integrity of the cells and tissue can damage the biological functionality of proteins, particularly enzymes.

Formalin fixation leads to degradation of mRNA, miRNA, and DNA as well as denaturation and modification of proteins in tissues. However, extraction and analysis of nucleic acids and proteins from formalin-fixed, paraffin-embedded tissues is possible using appropriate protocols.[14][15]

Selection and trimming

 
Items used for submitting specimens: (Biopsy) wrap, (biopsy) sponge, (tissue processing) cassette and (biopsy) bag.

Selection is the choice of relevant tissue in cases where it is not necessary to put the entire original tissue mass through further processing. The remainder may remain fixated in case it needs to be examined at a later time.

Trimming is the cutting of tissue samples in order to expose the relevant surfaces for later sectioning. It also creates tissue samples of appropriate size to fit into cassettes.[16]

Embedding

Tissues are embedded in a harder medium both as a support and to allow the cutting of thin tissue slices.[9][5] In general, water must first be removed from tissues (dehydration) and replaced with a medium that either solidifies directly, or with an intermediary fluid (clearing) that is miscible with the embedding media.[12]

Paraffin wax

 
Histologic sample being embedded in paraffin wax (tissue is held at the bottom of a metal mold, and more molten paraffin is poured over it to fill it).

For light microscopy, paraffin wax is the most frequently used embedding material.[12][13] Paraffin is immiscible with water, the main constituent of biological tissue, so it must first be removed in a series of dehydration steps.[12] Samples are transferred through a series of progressively more concentrated ethanol baths, up to 100% ethanol to remove remaining traces of water.[9][12] Dehydration is followed by a clearing agent (typically xylene[13] although other environmental safe substitutes are in use[13]) which removes the alcohol and is miscible with the wax, finally melted paraffin wax is added to replace the xylene and infiltrate the tissue.[9] In most histology, or histopathology laboratories the dehydration, clearing, and wax infiltration are carried out in tissue processors which automate this process.[13] Once infiltrated in paraffin, tissues are oriented in molds which are filled with wax; once positioned, the wax is cooled, solidifying the block and tissue.[13][12]

Other materials

Paraffin wax does not always provide a sufficiently hard matrix for cutting very thin sections (which are especially important for electron microscopy).[12] Paraffin wax may also be too soft in relation to the tissue, the heat of the melted wax may alter the tissue in undesirable ways, or the dehydrating or clearing chemicals may harm the tissue.[12] Alternatives to paraffin wax include, epoxy, acrylic, agar, gelatin, celloidin, and other types of waxes.[12][17]

In electron microscopy epoxy resins are the most commonly employed embedding media,[9] but acrylic resins are also used, particularly where immunohistochemistry is required.

For tissues to be cut in a frozen state, tissues are placed in a water-based embedding medium. Pre-frozen tissues are placed into molds with the liquid embedding material, usually a water-based glycol, OCT, TBS, Cryogen, or resin, which is then frozen to form hardened blocks.

Sectioning

Main article: Microtome
 
Histologic sample being cut on a microtome.

For light microscopy, a knife mounted in a microtome is used to cut tissue sections (typically between 5-15 micrometers thick) which are mounted on a glass microscope slide.[9] For transmission electron microscopy (TEM), a diamond or glass knife mounted in an ultramicrotome is used to cut between 50 and 150 nanometer thick tissue sections.[9]

Staining

Main article: Staining

Biological tissue has little inherent contrast in either the light or electron microscope.[17] Staining is employed to give both contrast to the tissue as well as highlighting particular features of interest. When the stain is used to target a specific chemical component of the tissue (and not the general structure), the term histochemistry is used.[9]

Light microscopy

 
Masson's trichrome staining on rat trachea.

Hematoxylin and eosin (H&E stain) is one of the most commonly used stains in histology to show the general structure of the tissue.[9][18] Hematoxylin stains cell nuclei blue; eosin, an acidic dye, stains the cytoplasm and other tissues in different stains of pink.[9][12]

In contrast to H&E, which is used as a general stain, there are many techniques that more selectively stain cells, cellular components, and specific substances.[12] A commonly performed histochemical technique that targets a specific chemical is the Perls' Prussian blue reaction, used to demonstrate iron deposits[12] in diseases like hemochromatosis. The Nissl method for Nissl substance and Golgi's method (and related silver stains) are useful in identifying neurons are other examples of more specific stains.[12]

Historadiography

In historadiography, a slide (sometimes stained histochemically) is X-rayed. More commonly, autoradiography is used in visualizing the locations to which a radioactive substance has been transported within the body, such as cells in S phase (undergoing DNA replication) which incorporate tritiated thymidine, or sites to which radiolabeled nucleic acid probes bind in in situ hybridization. For autoradiography on a microscopic level, the slide is typically dipped into liquid nuclear tract emulsion, which dries to form the exposure film. Individual silver grains in the film are visualized with dark field microscopy.

Immunohistochemistry

Main article: immunohistochemistry

Recently, antibodies have been used to specifically visualize proteins, carbohydrates, and lipids. This process is called immunohistochemistry, or when the stain is a fluorescent molecule, immunofluorescence. This technique has greatly increased the ability to identify categories of cells under a microscope. Other advanced techniques, such as nonradioactive in situ hybridization, can be combined with immunochemistry to identify specific DNA or RNA molecules with fluorescent probes or tags that can be used for immunofluorescence and enzyme-linked fluorescence amplification (especially alkaline phosphatase and tyramide signal amplification). Fluorescence microscopy and confocal microscopy are used to detect fluorescent signals with good intracellular detail.

Electron microscopy

Main article: Electron microscope § Sample preparation

For electron microscopy heavy metals are typically used to stain tissue sections.[9] Uranyl acetate and lead citrate are commonly used to impart contrast to tissue in the electron microscope.[9]

Specialized techniques

Cryosectioning

Main article: Frozen section procedure

Similar to the frozen section procedure employed in medicine, cryosectioning is a method to rapidly freeze, cut, and mount sections of tissue for histology. The tissue is usually sectioned on a cryostat or freezing microtome.[12] The frozen sections are mounted on a glass slide and may be stained to enhance the contrast between different tissues. Unfixed frozen sections can be used for studies requiring enzyme localization in tissues and cells. Tissue fixation is required for certain procedures such as antibody-linked immunofluorescence staining. Frozen sections are often prepared during surgical removal of tumors to allow rapid identification of tumor margins, as in Mohs surgery, or determination of tumor malignancy, when a tumor is discovered incidentally during surgery.

Ultramicrotomy

Main article: Ultramicrotomy

Ultramicrotomy is a method of preparing extremely thin sections for transmission electron microscope (TEM) analysis. Tissues are commonly embedded in epoxy or other plastic resin.[9] Very thin sections (less than 0.1 micrometer in thickness) are cut using diamond or glass knives on an ultramicrotome.[12]

Artifacts

Artifacts are structures or features in tissue that interfere with normal histological examination. Artifacts interfere with histology by changing the tissues appearance and hiding structures. Tissue processing artifacts can include pigments formed by fixatives,[12] shrinkage, washing out of cellular components, color changes in different tissues types and alterations of the structures in the tissue. An example is mercury pigment left behind after using Zenker's fixative to fix a section.[12] Formalin fixation can also leave a brown to black pigment under acidic conditions.[12]

History

 
Santiago Ramón y Cajal in his laboratory.

In the 17th century the Italian Marcello Malpighi used microscopes to study tiny biological entities; some regard him as the founder of the fields of histology and microscopic pathology.[19][20] Malpighi analyzed several parts of the organs of bats, frogs and other animals under the microscope. While studying the structure of the lung, Malpighi noticed its membranous alveoli and the hair-like connections between veins and arteries, which he named capillaries. His discovery established how the oxygen breathed in enters the blood stream and serves the body.[21]

In the 19th century histology was an academic discipline in its own right. The French anatomist Xavier Bichat introduced the concept of tissue in anatomy in 1801,[22] and the term "histology" (German: Histologie), coined to denote the "study of tissues", first appeared in a book by Karl Meyer in 1819.[23][24][19] Bichat described twenty-one human tissues, which can be subsumed under the four categories currently accepted by histologists.[25] The usage of illustrations in histology, deemed as useless by Bichat, was promoted by Jean Cruveilhier.[26][when?]

In the early 1830s Purkynĕ invented a microtome with high precision.[24]

During the 19th century many fixation techniques were developed by Adolph Hannover (solutions of chromates and chromic acid), Franz Schulze and Max Schultze (osmic acid), Alexander Butlerov (formaldehyde) and Benedikt Stilling (freezing).[24]

Mounting techniques were developed by Rudolf Heidenhain (1824-1898), who introduced gum Arabic; Salomon Stricker (1834-1898), who advocated a mixture of wax and oil; and Andrew Pritchard (1804-1884) who, in 1832, used a gum/isinglass mixture. In the same year, Canada balsam appeared on the scene, and in 1869 Edwin Klebs (1834-1913) reported that he had for some years embedded his specimens in paraffin.[27]

The 1906 Nobel Prize in Physiology or Medicine was awarded to histologists Camillo Golgi and Santiago Ramon y Cajal. They had conflicting interpretations of the neural structure of the brain based on differing interpretations of the same images. Ramón y Cajal won the prize for his correct theory, and Golgi for the silver-staining technique that he invented to make it possible.[28]

Future directions

In vivo histology

Currently there is intense interest in developing techniques for in vivo histology (predominantly using MRI), which would enable doctors to non-invasively gather information about healthy and diseased tissues in living patients, rather than from fixed tissue samples.[29][30][31][32]

Notes

  1. ^ The word histology (/hɪstˈɒləi/) is Neo-Latin using the combining forms of histo- + -logy, yielding "tissue study", from the Greek words ἱστός histos, "tissue", and -λογία, "study".

References

  1. ^ "Microanatomy definition and meaning". Collins English Dictionary.
  2. ^ "Histology | physiology". Encyclopedia Britannica. Retrieved 2018-10-29.
  3. ^ . Defined Term. Archived from the original on 2018-10-29. Retrieved 2018-10-29.
  4. ^ Maximow, Alexander A.; Bloom, William (1957). A textbook of Histology (Seventh ed.). Philadelphia: W. B. Saunders Company.
  5. ^ a b c d e f g h Leeson, Thomas S.; Leeson, C. Roland (1981). Histology (Fourth ed.). W. B. Saunders Company. p. 600. ISBN 978-0721657042.
  6. ^ a b c Stedman's medical dictionary (27th ed.). Lippincott Williams & Wilkins. 2006. ISBN 978-0683400076.
  7. ^ Padian, Kevin; Lamm, Ellen-Thérèse, eds. (2013). Bone histology of fossil tetrapods : Advancing methods, analysis, and interpretation (1st ed.). University of California Press. p. 298. ISBN 978-0-520-27352-8.
  8. ^ Canoville A, Chinsamy A (2015). "Bone Microstructure of the Stereospondyl Lydekkerina Huxleyi Reveals Adaptive Strategies to the Harsh Post Permian-Extinction Environment". The Anatomical Record. 298 (7): 1237–54. doi:10.1002/ar.23160. PMID 25857487. S2CID 43628074.
  9. ^ a b c d e f g h i j k l m n o p q r Ross, Michael H.; Pawlina, Wojciech (2016). Histology : a text and atlas : with correlated cell and molecular biology (7th ed.). Wolters Kluwer. pp. 984p. ISBN 978-1451187427.
  10. ^ Rosai J (2007). "Why microscopy will remain a cornerstone of surgical pathology". Lab Invest. 87 (5): 403–8. doi:10.1038/labinvest.3700551. PMID 17401434. S2CID 27399409.
  11. ^ Titford, Michael; Bowman, Blythe (2012). "What May the Future Hold for Histotechnologists?". Laboratory Medicine. 43 (suppl 2): e5–e10. doi:10.1309/LMXB668WDCBIAWJL. ISSN 0007-5027.
  12. ^ a b c d e f g h i j k l m n o p q r s t Bancroft, John; Stevens, Alan, eds. (1982). The Theory and Practice of Histological Techniques (2nd ed.). Longman Group Limited.
  13. ^ a b c d e f Wick, Mark R. (2019). "The hematoxylin and eosin stain in anatomic pathology—An often-neglected focus of quality assurance in the laboratory". Seminars in Diagnostic Pathology. 36 (5): 303–311. doi:10.1053/j.semdp.2019.06.003. ISSN 0740-2570. PMID 31230963. S2CID 195326749.
  14. ^ Weiss AT, Delcour NM, Meyer A, Klopfleisch R (July 2011). "Efficient and cost-effective extraction of genomic DNA from formalin-fixed and paraffin-embedded tissues". Veterinary Pathology. 48 (4): 834–8. doi:10.1177/0300985810380399. PMID 20817894. S2CID 34974790.
  15. ^ Bennike TB, Kastaniegaard K, Padurariu S, Gaihede M, Birkelund S, Andersen V, Stensballe A (March 2016). "Comparing the proteome of snap frozen, RNAlater preserved, and formalin-fixed paraffin-embedded human tissue samples". EuPA Open Proteomics. 10: 9–18. doi:10.1016/j.euprot.2015.10.001. PMC 5988570. PMID 29900094.
  16. ^ Slaoui, Mohamed; Fiette, Laurence (2011). "Histopathology Procedures: From Tissue Sampling to Histopathological Evaluation". Drug Safety Evaluation. Methods in Molecular Biology. Vol. 691. pp. 69–82. doi:10.1007/978-1-60761-849-2_4. ISBN 978-1-60327-186-8. ISSN 1064-3745. PMID 20972747.
  17. ^ a b Drury, R. A. B.; Wallington, E. A. (1980). Carleton's Histological Technique (5th ed.). Oxford University Press. p. 520. ISBN 0-19-261310-3.
  18. ^ Dapson RW, Horobin RW (2009). "Dyes from a twenty-first century perspective". Biotech Histochem. 84 (4): 135–7. doi:10.1080/10520290902908802. PMID 19384743. S2CID 28563610.
  19. ^ a b Bracegirdle B (1977). "The History of Histology: A Brief Survey of Sources". History of Science. 15 (2): 77–101. Bibcode:1977HisSc..15...77B. doi:10.1177/007327537701500201. S2CID 161338778.
  20. ^ Motta PM (1998). "Marcello Malpighi and the foundations of functional microanatomy". Anat Rec. 253 (1): 10–2. doi:10.1002/(SICI)1097-0185(199802)253:1<10::AID-AR7>3.0.CO;2-I. PMID 9556019.
  21. ^ Adelmann HB, Malpighi M (1966). Marcello Malpighi and the Evolution of Embryology. Vol. 5. Ithaca, N.Y.: Cornell University Press. OCLC 306783.
  22. ^ Bichat X (1801). "Considérations générales". Anatomie générale appliquée à la physiologie et à la médecine (in French). Paris: Chez Brosson, Gabon et Cie, Libraires, rue Pierre-Sarrazin, no. 7, et place de l'École de Médecine. pp. cvj–cxj.
  23. ^ Mayer AF (1819). Ueber Histologie und eine neue Eintheilung der Gewebe des menschlichen Körpers (in German). Bonn: Adolph Marcus.
  24. ^ a b c Bock O (2015). "A history of the development of histology up to the end of the nineteenth century". Research. 2: 1283. doi:10.13070/rs.en.2.1283 (inactive 31 December 2022).{{cite journal}}: CS1 maint: DOI inactive as of December 2022 (link)
  25. ^ Rather LJ (1978). The Genesis of Cancer: A Study in the History of Ideas. Baltimore: Johns Hopkins University Press. ISBN 9780801821035. Most of Bichat's twenty-one tissues can be subsumed under the four categories generally accepted by contemporary histologists; epithelium, connective tissue, muscle, and nerve. Four of Bichat's tissues fall under the heading of epithelium (epidermoid, mucous, serous, and synovial); six under connective tissue (dermoid, fibrous, fibrocartilaginous, cartilaginous, osseous, and cellular); two under muscle; and two under nerve — the distinction between nervous governing "animal" life and nervous governing "organic" life corresponds with that between the voluntary and involuntary nervous systems. The arteries and the veins, long sources of contention, are classified today as compound tissues. The absorbents and the exhalants (which Bichat thought to be open-ended vessels) have dropped out or been replaced by the lymphatics. His medullary system has no counterpart among the present-day tissues.
  26. ^ Meli DB (2017). Visualizing disease: the art and history of pathological illustrations. Chicago: The University of Chicago Press.[page needed]
  27. ^ Bock, Ortwin (2015-01-05). "A history of the development of histology up to the end of the nineteenth century". Research.
  28. ^ "The Nobel Prize in Physiology or Medicine 1906". NobelPrize.org.
  29. ^ Dominietto, Marco; Rudin, Markus (2014). "Could magnetic resonance provide in vivo histology?". Frontiers in Genetics. 4: 298. doi:10.3389/fgene.2013.00298. ISSN 1664-8021. PMC 3888945. PMID 24454320.
  30. ^ Delnoij, Thijs; van Suylen, Robert Jan; Cleutjens, Jack P.M.; Schalla, Simon; Bekkers, Sebastiaan C.A.M. (October 2009). "In vivo histology by cardiovascular magnetic resonance imaging". European Heart Journal. 30 (20): 2492. doi:10.1093/eurheartj/ehp319. ISSN 1522-9645. PMID 19696188.
  31. ^ Bridge, Holly; Clare, Stuart (2006-01-29). "High-resolution MRI: in vivo histology?". Philosophical Transactions of the Royal Society B: Biological Sciences. 361 (1465): 137–146. doi:10.1098/rstb.2005.1777. ISSN 0962-8436. PMC 1626544. PMID 16553313.
  32. ^ Deistung, Andreas; Schäfer, Andreas; Schweser, Ferdinand; Biedermann, Uta; Turner, Robert; Reichenbach, Jürgen R. (January 2013). "Toward in vivo histology: A comparison of quantitative susceptibility mapping (QSM) with magnitude-, phase-, and R2⁎-imaging at ultra-high magnetic field strength". NeuroImage. 65: 299–314. doi:10.1016/j.neuroimage.2012.09.055. PMID 23036448. S2CID 140122831.

External links

  •   Media related to Histology at Wikimedia Commons

May 12, 2023
histology, histography, redirects, here, study, history, science, historiography, help, also, known, microscopic, anatomy, microanatomy, branch, biology, that, studies, microscopic, anatomy, biological, tissues, microscopic, counterpart, gross, anatomy, which,. Histography redirects here For the study of history as a science see Historiography Histology help 1 also known as microscopic anatomy or microanatomy 1 is the branch of biology that studies the microscopic anatomy of biological tissues 2 3 4 5 Histology is the microscopic counterpart to gross anatomy which looks at larger structures visible without a microscope 5 6 Although one may divide microscopic anatomy into organology the study of organs histology the study of tissues and cytology the study of cells modern usage places all of these topics under the field of histology 5 In medicine histopathology is the branch of histology that includes the microscopic identification and study of diseased tissue 5 6 In the field of paleontology the term paleohistology refers to the histology of fossil organisms 7 8 Histologic specimen being placed on the stage of an optical microscope Human lung tissue stained with hematoxylin and eosin as seen under a microscope Contents 1 Biological tissues 1 1 Animal tissue classification 1 2 Plant tissue classification 2 Medical histology 2 1 Occupations 3 Sample preparation 3 1 Fixation 3 2 Selection and trimming 3 3 Embedding 3 3 1 Paraffin wax 3 3 2 Other materials 3 4 Sectioning 3 5 Staining 3 5 1 Light microscopy 3 5 2 Historadiography 3 5 3 Immunohistochemistry 3 5 4 Electron microscopy 3 6 Specialized techniques 3 6 1 Cryosectioning 3 6 2 Ultramicrotomy 3 7 Artifacts 4 History 5 Future directions 5 1 In vivo histology 6 Notes 7 References 8 External linksBiological tissues EditAnimal tissue classification Edit Main article Anatomy Animal tissues There are four basic types of animal tissues muscle tissue nervous tissue connective tissue and epithelial tissue 5 9 All animal tissues are considered to be subtypes of these four principal tissue types for example blood is classified as connective tissue since the blood cells are suspended in an extracellular matrix the plasma 9 Epithelium Simple epithelium Simple squamous epithelium Simple cuboidal epithelium Simple columnar epithelium Pseudostratified columnar epithelium Stratified epithelium Stratified squamous epithelium Stratified cuboidal epithelium Stratified columnar epithelium Transitional epithelium Multicellular glands Muscle tissue Smooth muscle Skeletal muscle Cardiac muscle Connective tissue General connective tissue Loose connective tissue Dense connective tissue Special connective tissue Cartilage Bone Hemopoietic Blood Lymph Nervous tissue Central nervous system Peripheral nervous system Special receptors Plant tissue classification Edit Histologic section of a plant stem Alliaria petiolata Main article Plant Anatomy For plants the study of their tissues falls under the field of plant anatomy with the following four main types Dermal tissue Vascular tissue Ground tissue Meristematic tissueMedical histology EditHistopathology is the branch of histology that includes the microscopic identification and study of diseased tissue 5 6 It is an important part of anatomical pathology and surgical pathology as accurate diagnosis of cancer and other diseases often requires histopathological examination of tissue samples 10 Trained physicians frequently licensed pathologists perform histopathological examination and provide diagnostic information based on their observations Occupations Edit The field of histology that includes the preparation of tissues for microscopic examination is known as histotechnology Job titles for the trained personnel who prepare histological specimens for examination are numerous and include histotechnicians histotechnologists 11 histology technicians and technologists medical laboratory technicians and biomedical scientists Sample preparation EditMost histological samples need preparation before microscopic observation these methods depend on the specimen and method of observation 9 Fixation Edit Main article Fixation histology Histologic section of a fossilized invertebrate Ordovician bryozoan Chemical fixatives are used to preserve and maintain the structure of tissues and cells fixation also hardens tissues which aids in cutting the thin sections of tissue needed for observation under the microscope 5 12 Fixatives generally preserve tissues and cells by irreversibly cross linking proteins 12 The most widely used fixative for light microscopy is 10 neutral buffered formalin or NBF 4 formaldehyde in phosphate buffered saline 13 12 9 For electron microscopy the most commonly used fixative is glutaraldehyde usually as a 2 5 solution in phosphate buffered saline 9 Other fixatives used for electron microscopy are osmium tetroxide or uranyl acetate 9 The main action of these aldehyde fixatives is to cross link amino groups in proteins through the formation of methylene bridges CH2 in the case of formaldehyde or by C5H10 cross links in the case of glutaraldehyde This process while preserving the structural integrity of the cells and tissue can damage the biological functionality of proteins particularly enzymes Formalin fixation leads to degradation of mRNA miRNA and DNA as well as denaturation and modification of proteins in tissues However extraction and analysis of nucleic acids and proteins from formalin fixed paraffin embedded tissues is possible using appropriate protocols 14 15 Selection and trimming Edit Items used for submitting specimens Biopsy wrap biopsy sponge tissue processing cassette and biopsy bag Selection is the choice of relevant tissue in cases where it is not necessary to put the entire original tissue mass through further processing The remainder may remain fixated in case it needs to be examined at a later time Trimming is the cutting of tissue samples in order to expose the relevant surfaces for later sectioning It also creates tissue samples of appropriate size to fit into cassettes 16 Embedding Edit Tissues are embedded in a harder medium both as a support and to allow the cutting of thin tissue slices 9 5 In general water must first be removed from tissues dehydration and replaced with a medium that either solidifies directly or with an intermediary fluid clearing that is miscible with the embedding media 12 Paraffin wax Edit Histologic sample being embedded in paraffin wax tissue is held at the bottom of a metal mold and more molten paraffin is poured over it to fill it For light microscopy paraffin wax is the most frequently used embedding material 12 13 Paraffin is immiscible with water the main constituent of biological tissue so it must first be removed in a series of dehydration steps 12 Samples are transferred through a series of progressively more concentrated ethanol baths up to 100 ethanol to remove remaining traces of water 9 12 Dehydration is followed by a clearing agent typically xylene 13 although other environmental safe substitutes are in use 13 which removes the alcohol and is miscible with the wax finally melted paraffin wax is added to replace the xylene and infiltrate the tissue 9 In most histology or histopathology laboratories the dehydration clearing and wax infiltration are carried out in tissue processors which automate this process 13 Once infiltrated in paraffin tissues are oriented in molds which are filled with wax once positioned the wax is cooled solidifying the block and tissue 13 12 Other materials Edit Paraffin wax does not always provide a sufficiently hard matrix for cutting very thin sections which are especially important for electron microscopy 12 Paraffin wax may also be too soft in relation to the tissue the heat of the melted wax may alter the tissue in undesirable ways or the dehydrating or clearing chemicals may harm the tissue 12 Alternatives to paraffin wax include epoxy acrylic agar gelatin celloidin and other types of waxes 12 17 In electron microscopy epoxy resins are the most commonly employed embedding media 9 but acrylic resins are also used particularly where immunohistochemistry is required For tissues to be cut in a frozen state tissues are placed in a water based embedding medium Pre frozen tissues are placed into molds with the liquid embedding material usually a water based glycol OCT TBS Cryogen or resin which is then frozen to form hardened blocks Sectioning Edit Main article Microtome Histologic sample being cut on a microtome For light microscopy a knife mounted in a microtome is used to cut tissue sections typically between 5 15 micrometers thick which are mounted on a glass microscope slide 9 For transmission electron microscopy TEM a diamond or glass knife mounted in an ultramicrotome is used to cut between 50 and 150 nanometer thick tissue sections 9 Staining Edit Main article Staining Biological tissue has little inherent contrast in either the light or electron microscope 17 Staining is employed to give both contrast to the tissue as well as highlighting particular features of interest When the stain is used to target a specific chemical component of the tissue and not the general structure the term histochemistry is used 9 Light microscopy Edit Masson s trichrome staining on rat trachea Hematoxylin and eosin H amp E stain is one of the most commonly used stains in histology to show the general structure of the tissue 9 18 Hematoxylin stains cell nuclei blue eosin an acidic dye stains the cytoplasm and other tissues in different stains of pink 9 12 In contrast to H amp E which is used as a general stain there are many techniques that more selectively stain cells cellular components and specific substances 12 A commonly performed histochemical technique that targets a specific chemical is the Perls Prussian blue reaction used to demonstrate iron deposits 12 in diseases like hemochromatosis The Nissl method for Nissl substance and Golgi s method and related silver stains are useful in identifying neurons are other examples of more specific stains 12 Historadiography Edit In historadiography a slide sometimes stained histochemically is X rayed More commonly autoradiography is used in visualizing the locations to which a radioactive substance has been transported within the body such as cells in S phase undergoing DNA replication which incorporate tritiated thymidine or sites to which radiolabeled nucleic acid probes bind in in situ hybridization For autoradiography on a microscopic level the slide is typically dipped into liquid nuclear tract emulsion which dries to form the exposure film Individual silver grains in the film are visualized with dark field microscopy Immunohistochemistry Edit Main article immunohistochemistry Recently antibodies have been used to specifically visualize proteins carbohydrates and lipids This process is called immunohistochemistry or when the stain is a fluorescent molecule immunofluorescence This technique has greatly increased the ability to identify categories of cells under a microscope Other advanced techniques such as nonradioactive in situ hybridization can be combined with immunochemistry to identify specific DNA or RNA molecules with fluorescent probes or tags that can be used for immunofluorescence and enzyme linked fluorescence amplification especially alkaline phosphatase and tyramide signal amplification Fluorescence microscopy and confocal microscopy are used to detect fluorescent signals with good intracellular detail Electron microscopy Edit Main article Electron microscope Sample preparation For electron microscopy heavy metals are typically used to stain tissue sections 9 Uranyl acetate and lead citrate are commonly used to impart contrast to tissue in the electron microscope 9 Specialized techniques Edit Cryosectioning Edit Main article Frozen section procedure Similar to the frozen section procedure employed in medicine cryosectioning is a method to rapidly freeze cut and mount sections of tissue for histology The tissue is usually sectioned on a cryostat or freezing microtome 12 The frozen sections are mounted on a glass slide and may be stained to enhance the contrast between different tissues Unfixed frozen sections can be used for studies requiring enzyme localization in tissues and cells Tissue fixation is required for certain procedures such as antibody linked immunofluorescence staining Frozen sections are often prepared during surgical removal of tumors to allow rapid identification of tumor margins as in Mohs surgery or determination of tumor malignancy when a tumor is discovered incidentally during surgery Ultramicrotomy Edit Green algae under a Transmission electron microscope Main article Ultramicrotomy Ultramicrotomy is a method of preparing extremely thin sections for transmission electron microscope TEM analysis Tissues are commonly embedded in epoxy or other plastic resin 9 Very thin sections less than 0 1 micrometer in thickness are cut using diamond or glass knives on an ultramicrotome 12 Artifacts Edit Artifacts are structures or features in tissue that interfere with normal histological examination Artifacts interfere with histology by changing the tissues appearance and hiding structures Tissue processing artifacts can include pigments formed by fixatives 12 shrinkage washing out of cellular components color changes in different tissues types and alterations of the structures in the tissue An example is mercury pigment left behind after using Zenker s fixative to fix a section 12 Formalin fixation can also leave a brown to black pigment under acidic conditions 12 History Edit Santiago Ramon y Cajal in his laboratory In the 17th century the Italian Marcello Malpighi used microscopes to study tiny biological entities some regard him as the founder of the fields of histology and microscopic pathology 19 20 Malpighi analyzed several parts of the organs of bats frogs and other animals under the microscope While studying the structure of the lung Malpighi noticed its membranous alveoli and the hair like connections between veins and arteries which he named capillaries His discovery established how the oxygen breathed in enters the blood stream and serves the body 21 In the 19th century histology was an academic discipline in its own right The French anatomist Xavier Bichat introduced the concept of tissue in anatomy in 1801 22 and the term histology German Histologie coined to denote the study of tissues first appeared in a book by Karl Meyer in 1819 23 24 19 Bichat described twenty one human tissues which can be subsumed under the four categories currently accepted by histologists 25 The usage of illustrations in histology deemed as useless by Bichat was promoted by Jean Cruveilhier 26 when In the early 1830s Purkynĕ invented a microtome with high precision 24 During the 19th century many fixation techniques were developed by Adolph Hannover solutions of chromates and chromic acid Franz Schulze and Max Schultze osmic acid Alexander Butlerov formaldehyde and Benedikt Stilling freezing 24 Mounting techniques were developed by Rudolf Heidenhain 1824 1898 who introduced gum Arabic Salomon Stricker 1834 1898 who advocated a mixture of wax and oil and Andrew Pritchard 1804 1884 who in 1832 used a gum isinglass mixture In the same year Canada balsam appeared on the scene and in 1869 Edwin Klebs 1834 1913 reported that he had for some years embedded his specimens in paraffin 27 The 1906 Nobel Prize in Physiology or Medicine was awarded to histologists Camillo Golgi and Santiago Ramon y Cajal They had conflicting interpretations of the neural structure of the brain based on differing interpretations of the same images Ramon y Cajal won the prize for his correct theory and Golgi for the silver staining technique that he invented to make it possible 28 Future directions EditIn vivo histology Edit Currently there is intense interest in developing techniques for in vivo histology predominantly using MRI which would enable doctors to non invasively gather information about healthy and diseased tissues in living patients rather than from fixed tissue samples 29 30 31 32 Notes Edit The word histology h ɪ s t ˈ ɒ l e dʒ i is Neo Latin using the combining forms of histo logy yielding tissue study from the Greek words ἱstos histos tissue and logia study References Edit Microanatomy definition and meaning Collins English Dictionary Histology physiology Encyclopedia Britannica Retrieved 2018 10 29 DefinedTerm Histology Defined Term Archived from the original on 2018 10 29 Retrieved 2018 10 29 Maximow Alexander A Bloom William 1957 A textbook of Histology Seventh ed Philadelphia W B Saunders Company a b c d e f g h Leeson Thomas S Leeson C Roland 1981 Histology Fourth ed W B Saunders Company p 600 ISBN 978 0721657042 a b c Stedman s medical dictionary 27th ed Lippincott Williams amp Wilkins 2006 ISBN 978 0683400076 Padian Kevin Lamm Ellen Therese eds 2013 Bone histology of fossil tetrapods Advancing methods analysis and interpretation 1st ed University of California Press p 298 ISBN 978 0 520 27352 8 Canoville A Chinsamy A 2015 Bone Microstructure of the Stereospondyl Lydekkerina Huxleyi Reveals Adaptive Strategies to the Harsh Post Permian Extinction Environment The Anatomical Record 298 7 1237 54 doi 10 1002 ar 23160 PMID 25857487 S2CID 43628074 a b c d e f g h i j k l m n o p q r Ross Michael H Pawlina Wojciech 2016 Histology a text and atlas with correlated cell and molecular biology 7th ed Wolters Kluwer pp 984p ISBN 978 1451187427 Rosai J 2007 Why microscopy will remain a cornerstone of surgical pathology Lab Invest 87 5 403 8 doi 10 1038 labinvest 3700551 PMID 17401434 S2CID 27399409 Titford Michael Bowman Blythe 2012 What May the Future Hold for Histotechnologists Laboratory Medicine 43 suppl 2 e5 e10 doi 10 1309 LMXB668WDCBIAWJL ISSN 0007 5027 a b c d e f g h i j k l m n o p q r s t Bancroft John Stevens Alan eds 1982 The Theory and Practice of Histological Techniques 2nd ed Longman Group Limited a b c d e f Wick Mark R 2019 The hematoxylin and eosin stain in anatomic pathology An often neglected focus of quality assurance in the laboratory Seminars in Diagnostic Pathology 36 5 303 311 doi 10 1053 j semdp 2019 06 003 ISSN 0740 2570 PMID 31230963 S2CID 195326749 Weiss AT Delcour NM Meyer A Klopfleisch R July 2011 Efficient and cost effective extraction of genomic DNA from formalin fixed and paraffin embedded tissues Veterinary Pathology 48 4 834 8 doi 10 1177 0300985810380399 PMID 20817894 S2CID 34974790 Bennike TB Kastaniegaard K Padurariu S Gaihede M Birkelund S Andersen V Stensballe A March 2016 Comparing the proteome of snap frozen RNAlater preserved and formalin fixed paraffin embedded human tissue samples EuPA Open Proteomics 10 9 18 doi 10 1016 j euprot 2015 10 001 PMC 5988570 PMID 29900094 Slaoui Mohamed Fiette Laurence 2011 Histopathology Procedures From Tissue Sampling to Histopathological Evaluation Drug Safety Evaluation Methods in Molecular Biology Vol 691 pp 69 82 doi 10 1007 978 1 60761 849 2 4 ISBN 978 1 60327 186 8 ISSN 1064 3745 PMID 20972747 a b Drury R A B Wallington E A 1980 Carleton s Histological Technique 5th ed Oxford University Press p 520 ISBN 0 19 261310 3 Dapson RW Horobin RW 2009 Dyes from a twenty first century perspective Biotech Histochem 84 4 135 7 doi 10 1080 10520290902908802 PMID 19384743 S2CID 28563610 a b Bracegirdle B 1977 The History of Histology A Brief Survey of Sources History of Science 15 2 77 101 Bibcode 1977HisSc 15 77B doi 10 1177 007327537701500201 S2CID 161338778 Motta PM 1998 Marcello Malpighi and the foundations of functional microanatomy Anat Rec 253 1 10 2 doi 10 1002 SICI 1097 0185 199802 253 1 lt 10 AID AR7 gt 3 0 CO 2 I PMID 9556019 Adelmann HB Malpighi M 1966 Marcello Malpighi and the Evolution of Embryology Vol 5 Ithaca N Y Cornell University Press OCLC 306783 Bichat X 1801 Considerations generales Anatomie generale appliquee a la physiologie et a la medecine in French Paris Chez Brosson Gabon et Cie Libraires rue Pierre Sarrazin no 7 et place de l Ecole de Medecine pp cvj cxj Mayer AF 1819 Ueber Histologie und eine neue Eintheilung der Gewebe des menschlichen Korpers in German Bonn Adolph Marcus a b c Bock O 2015 A history of the development of histology up to the end of the nineteenth century Research 2 1283 doi 10 13070 rs en 2 1283 inactive 31 December 2022 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint DOI inactive as of December 2022 link Rather LJ 1978 The Genesis of Cancer A Study in the History of Ideas Baltimore Johns Hopkins University Press ISBN 9780801821035 Most of Bichat s twenty one tissues can be subsumed under the four categories generally accepted by contemporary histologists epithelium connective tissue muscle and nerve Four of Bichat s tissues fall under the heading of epithelium epidermoid mucous serous and synovial six under connective tissue dermoid fibrous fibrocartilaginous cartilaginous osseous and cellular two under muscle and two under nerve the distinction between nervous governing animal life and nervous governing organic life corresponds with that between the voluntary and involuntary nervous systems The arteries and the veins long sources of contention are classified today as compound tissues The absorbents and the exhalants which Bichat thought to be open ended vessels have dropped out or been replaced by the lymphatics His medullary system has no counterpart among the present day tissues Meli DB 2017 Visualizing disease the art and history of pathological illustrations Chicago The University of Chicago Press page needed Bock Ortwin 2015 01 05 A history of the development of histology up to the end of the nineteenth century Research The Nobel Prize in Physiology or Medicine 1906 NobelPrize org Dominietto Marco Rudin Markus 2014 Could magnetic resonance provide in vivo histology Frontiers in Genetics 4 298 doi 10 3389 fgene 2013 00298 ISSN 1664 8021 PMC 3888945 PMID 24454320 Delnoij Thijs van Suylen Robert Jan Cleutjens Jack P M Schalla Simon Bekkers Sebastiaan C A M October 2009 In vivo histology by cardiovascular magnetic resonance imaging European Heart Journal 30 20 2492 doi 10 1093 eurheartj ehp319 ISSN 1522 9645 PMID 19696188 Bridge Holly Clare Stuart 2006 01 29 High resolution MRI in vivo histology Philosophical Transactions of the Royal Society B Biological Sciences 361 1465 137 146 doi 10 1098 rstb 2005 1777 ISSN 0962 8436 PMC 1626544 PMID 16553313 Deistung Andreas Schafer Andreas Schweser Ferdinand Biedermann Uta Turner Robert Reichenbach Jurgen R January 2013 Toward in vivo histology A comparison of quantitative susceptibility mapping QSM with magnitude phase and R2 imaging at ultra high magnetic field strength NeuroImage 65 299 314 doi 10 1016 j neuroimage 2012 09 055 PMID 23036448 S2CID 140122831 External links Edit Medicine portal Media related to Histology at Wikimedia Commons Retrieved from https en wikipedia org w index php title Histology amp oldid 1153457438, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.