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Western University of Health Sciences

Mohammed Elsalanty

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histology biology anatomy medical science

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This document introduces tissue histology, focusing on epithelial and connective tissues. It explains different tissue types, their structures, and functions. The content delves into concepts like cell polarity, junctional complexes, and extracellular matrix components.

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Introduction to Tissue Histology Mohammed Elsalanty, MBBS, PhD College of Osteopathic Medicine of the Pacific Western University of Health Sciences PART I: Epithelial Tissue Epithelium Surface cover Origin: Ectoderm or endoderm...

Introduction to Tissue Histology Mohammed Elsalanty, MBBS, PhD College of Osteopathic Medicine of the Pacific Western University of Health Sciences PART I: Epithelial Tissue Epithelium Surface cover Origin: Ectoderm or endoderm Mostly identical cells attach to each other to form one or more layers Basement membrane (or basal lamina) separating it from underlying connective tissue (lamina propria) Epithelium Epithelial cells have polarity (direction): 1. Apical (free) surface, 2. Lateral surfaces (In between neighboring cells) 3. Basal surface (attached to the basal lamina) Avascular: nourishment by diffusion through basal lamina Highly regenerative and continuously renewing Classified based on the number of layers (simple and stratified) & the cell shape (squamous, cuboidal, & columnar) Functional Adaptation Cells strongly attach to as well as communicate with each other Basal layer attaches to the basement membrane and includes the stem cells JUNCTIONAL COMPLEXES Typically found near the cell apex 3 components: – Zonula Occludens or tight junctions – Zonula Adherens or anchoring junctions – Macula Adherens or desmosomes Gap junctions (small-molecule channels between neighboring epithelial cells) Formed by pairs of connexons, each composed of six protein subunits (connexins) that span the lipid bilayer of each cell membrane. Allows the free flow of electrolytes between attached cells Figure 4-7 Copyright © McGraw-Hill Companies laminin Basal lamina (BL) Reticular lamina (RL). Hemidesmosomes (H) Integrins bind the basal surface of the epithelial cell (C) to the basal lamina. X54,000. Figure 4-3 Copyright © McGraw-Hill Companies Apical Surface The surface facing the environment (whether the internal, such as a cavity, or external) Epithelial cells may possess apical specializations such as – Microvilli – Cilia Cilia Actively motile processes (5-10 μm in length) à Push stuff up and down pipes Each grows from a basal body during ciliogenesis Produce energy-dependent movement Types of Epithelium Simple (Single Layer) Stratified (Multiple Layers) Pseudostratified (Single layer that appear multiple) Transitional (Changes the number of layers) Simple Squamous Epithelium Single layer of flattened cells, very little cytoplasm and organelles Typically, cells maintain tight adhesion to each other and to the basement membrane Molecule transport possible by simple diffusion across the cells Examples: Alveolar lining (lung), endothelium (lining of all blood vessels and heart) & inner corneal epithelium Simple Cuboidal Epithelium Single layer of cubical cells with central nuclei More cytoplasm and organelles than SSE Examples: tubules in kidney, duct (drain) of lacrimal gland Simple Columnar Epithelium Single layer of tall cells (height 2-3X width) Often have cilia or microvilli on their apical surface Example: lining of most of the gastrointestinal tract Functions include secretion, absorption, and protection Stratified Epithelium Multiple layers Dividing (stem) cells in the basal layer Cells advance in differentiation as they are pushed towards the surface by newly formed cells. Surface cells eventually slough off Impermeable to water Highly protective (friction, elements, microorganisms, etc.) Can be keratinized or non-keratinized Examples: Oral mucosa, skin, conjunctiva, outer cornea Epithelium covering the lens: The lens capsule is a thick basement membrane secreted by subcapsular epithelium. Epithelium of the cornea: 1. External nonkeratinized stratified squamous epithelium (E): 5-6 cell-thick, densely supplied with sensory-free nerve endings à blinking reflex 2. Innermost layer of simple squamous endothelium (EN). Conjunctiva: Non-keratinized stratified epithelium Some mucous-producing (Goblet) cells Pseudostratified Columnar Epithelium Columnar cells that appear to stack in multiple layers because of the crowding, but all rest on a basal lamina (single layer) Often ciliated May have Goblet cells (mucous- secretion) Examples: trachea (respiratory epithelium) Transitional Epithelium Line a rapidly expandable cavity The number of layers decrease as the cavity becomes more distended. EMPTY Cell membrane remodels to line up the cells next to each other instead of being on top of each other Example: Urinary bladder FULL Glandular Epithelium Consists of a secretory & ductal components that is separated from CT by a basal lamina Simple columnar epithelium Example: Lacrimal Gland PART II: Connective Tissue Connective Tissue Network of supportive cells that produce extracellular matrix à Fibers + Ground Substance (hydrated gel of glycosaminoglycans - GAGs). Common characteristics: Origin: mesoderm Supportive cells produce extracellular matrix in between them Matrix is composed of fibrillar proteins + ground substance. Cells adhere to extracellular matrix, rather than to each other. Cellular and structural diversity and high mobility Fibroblasts Spindle-shaped Large active nuclei and eosinophilic cytoplasm Cellular processes resemble the collagen bundles Extracellular matrix has two major components: Ground substance: Gel-like Glycosaminoglycans (GAGs) Fibrillar proteins: for anchorage and mechanical integrity: 1. Collagen 2. Fibrillin 3. Elastin 4. Fibronectin. Type I collagen: 1. Most abundant collagen 2. Molecules packed into fibrils à fibers à bundled linked together by other collagen types. 3. Major component the sclera Silver Stain or PAS X100 Type III collagen (reticular fibers): Form microscopic tissue chambers/compartments (e.g. in endocrine glands, bone marrow, and lymphoid organs) Copyright © McGraw-Hill Companies Elastic fibers or lamellae (sheets): Elastin core, surrounded by GAGs (heparan sulphate), and fibrillin. Location: Wherever stretching is needed: Skin, lung, blood vessels Copyright © McGraw-Hill Companies Collagen Subtypes Fibronectin Most common glycoprotein of the ECM Essential for cell-to-ECM interactions Binds to cell membrane-spanning receptor proteins called integrins, as well as other extracellular matrix components (e.g. collagen, fibrin, and heparan sulfate) Regulates the deposition and orientation of collagen in the matrix Ground Substance: Glycosaminoglycans (GAGs): Large polysaccharides linked (by linker proteins) to core proteins to form proteoglycans. The large molecule is negatively charged and traps water and à hydrated gel Gives turgor and regulate the trafficking of molecules through matrix. Connective Tissue Proper Loose (areolar) CT Dense Regular CT Dense Irregular CT Loose Connective Tissue Cellular Resident cells: components - fibroblasts - synthesize extracellular matrix - macrophages - Innate immune response - mast cells - adaptive immunity and wound healing; involved in allergic reactions - adipocytes - synthesize and store fat - mesenchymal stem cells - Back up cells Transient cells: - All other immune cells Extracellular Ground substance - Glycoproteins (fibronectin) matrix and proteoglycans Fibers: Col III, (some IV and VII) and elastic fibers (Elastin + Fibrillin) Example Lamina propria underneath epithelium Dense Regular CT: Densely packed, parallel, collagen fibers (Col I), lots of fibroblasts, & very little matrix Location: Sclera, Corneal Stroma (mixture of several collagen types), tendons, and ligaments (stress in only one direction). The sclera is a dense layer of connective tissue rich in collagen type I, arranged in parallel bundles. Corneal stroma: – 90% of corneal thickness – ~ 200 layers of crisscrossing collagen type I fibers, each is about 1.5 to 2.5 microns, as well as flat fibroblasts – Light scatter by each fiber is cancelled out by destructive interference of another à transparency Dense Irregular CT: Collagen bundles (mainly type I, some III) packed but irregularly arranged and interwoven (sheets rather than cables) Location: Reticular layer of the dermis (skin) Tenon’s Capsule (fascia bulbi) A dense membrane which envelops the eyeball from the optic nerve to the limbus, separating it from the orbital fat and forming a socket in which it plays Extraocular muscles pass through openings in the Tenon’s capsule to insert into the sclera White adipose tissue Space filling (e.g. subcutaneous, axilla, pelvis, and around viscera) Triglyceride storage and mobilization, thermal insulator, padding, hormonal function Lobules, each has lipid-filled cells and is surrounded by fibrous tissue Visceral fat (~10% of white fat) is located around viscera (internal organs) More linked to metabolic disorders, cancer, heart disease, stroke, and Alzheimer’s than subcutaneous fat. Brown adipose tissue Only small amounts in human adults, mainly around the adrenal glands. Involved in the regulation of body temperature and body weight. Highly metabolically active. Cells are packed with mitochondria, in between lipid-storing cells. Bone Matrix: Type I collagen (structure), plus some proteoglycans and glycoproteins (regulation) Cells that make Type I collagen fibers then mineralize them with hydroxyapatite crystals [Ca10(PO4)6(OH)2]. Mineralization is responsible for bone hardness, while organic matrix provides flexibility (resilience). Bone Cells Osteoblasts (Bone formation) Osteoclasts (Bone resorption) Osteocytes (Bone control centers?)

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